Patent Description:
As performance of a camera function provided in a smartphone, a tablet personal computer (PC), or the like improves, a trend of porting a camera technology typically of a digital single-lens camera to the camera function is accelerated. Therefore, a demand for better color representation of an image photographed by the smartphone or the like has increased, and color correction by providing an advanced correction block such as a 3D lookup table (3D-LUT) in the smartphone or the like is effective means.

However, the difficulty of designing color reproduction using a 3D lookup table (3D-LUT) is high, and an enormous work of parameter setting is required. In particular, the color representation of captured images differs due to variations in image sensors and the like even in the same model, as well as between different models, and thus, it takes an extreme long time to set 3D-LUT parameters.

Therefore, the present disclosure proposes an information processing apparatus, an information processing terminal, a method, a program, and a model capable of generating the 3D-LUT more easily. Prior art includes: <NPL>; and
<NPL>. Each of these disclosures describes a prior art device.

Further aspects of the present disclosure are defined by the dependent claims.

Hereinafter, the present embodiment will be detailed with reference to the drawings. Note that, in the present specification and the drawings, substantially the same parts are given the same reference signs to omit duplicate description.

The description will be given in the following order.

First, a functional configuration example of an information processing apparatus <NUM> according to the present embodiment will be described. The information processing apparatus <NUM> may be a server device managed by a manufacturer of smartphones or cameras, or may be a stationary terminal or a notebook personal computer (PC). Note that the information processing apparatus <NUM> may also be a cloud server device managed by a company that provides a cloud computing service. Furthermore, the information processing apparatus <NUM> does not need to be configured by one computer, and may be a distributed computing system configured by a plurality of computers.

The information processing apparatus <NUM> constructs a learning model by learning training data including a developed image of an image obtained by photographing a color sample under a standard light source by a first camera device as input data and a 3D lookup table (3D-LUT) used for developing the image as correct answer data. Then, the learning model is used for estimating a 3D-LUT for reproducing, by the first camera device, a color of the color sample in another image photographed by a second camera device. Note that the camera device may be a smartphone or the like equipped with a camera function, or may be a camera itself such as a digital camera.

<FIG> is a block diagram illustrating a functional configuration example of the information processing apparatus <NUM> according to the present embodiment. As illustrated in <FIG>, the information processing apparatus <NUM> according to the present embodiment includes a storage unit <NUM>, an acquisition unit <NUM>, a learning unit <NUM>, an estimation unit <NUM>, a generation unit <NUM>, and a control unit <NUM>.

The storage unit <NUM> according to the present embodiment is a storage area for temporarily or permanently storing various programs and data. The storage unit <NUM> may store programs and data for the information processing apparatus <NUM> to execute various functions. As a specific example, the storage unit <NUM> may store the learning model (color reproduction LUT estimation model) for estimating the 3D-LUT that is used for reproducing the color of the image from the developed image obtained by photographing the color sample, the training data for learning, and management data for managing various settings. Obviously, the above is merely an example, and the type of data stored in the storage unit <NUM> is not particularly limited.

In a learning phase of the color reproduction LUT estimation model, the acquisition unit <NUM> according to the present embodiment acquires a developed image of the image obtained by photographing the color sample (corresponding to a "first image") by a camera device (corresponding to a "first camera device") for reproducing color representation of another camera device, and the 3D-LUT used for developing the image. Furthermore, in a recognition (estimation) phase of the color reproduction LUT estimation model, the acquisition unit <NUM> acquires a developed image of an image obtained by photographing the color sample (corresponding to a "second image") by a camera device for which the 3D-LUT is estimated (corresponding to a "second camera device").

The learning unit <NUM> according to the present embodiment learns the training data including the developed image of the image obtained by photographing the color sample under the standard light source (corresponding to the "first image") acquired by the acquisition unit <NUM> as the input data and the 3D-LUT used for developing the image (corresponding to a "first 3D-LUT") as the correct answer data to construct the color reproduction LUT estimation model.

Note that the color reproduction LUT estimation model of the present embodiment includes an input layer to which the developed image of the image obtained by photographing the color sample is input, an output layer, a first element belonging to any layer from the input layer to the output layer other than the output layer, and a second element whose value is calculated based on the first element and a weight of the first element. The color reproduction LUT estimation model causes the information processing apparatus <NUM> to output, from the output layer, the 3D-LUT for reproducing the color of the developed image of the image obtained by photographing the color sample by performing an operation based on the first element and the weight of the first element. The first element is each element belonging to each layer other than the output layer according to the image input to the input layer.

Note that a generation device (e.g., the information processing apparatus <NUM> such as a server device) that generates the learning model of the present embodiment may generate the above-described learning model using any learning algorithm. For example, the generation device may generate the learning model of the present embodiment using a learning algorithm such as a neural network (NN), a support vector machine (SVM), or reinforcement learning. As an example, it is assumed that the generation device generates the learning model of the present embodiment using the NN. In this case, the learning model may have the input layer including one or more neurons, an intermediate layer including one or more neurons, and the output layer including one or more neurons.

Here, it is assumed that the learning model according to the present embodiment is realized by a regression model indicated by "y = a<NUM> * x<NUM> + a<NUM> * x<NUM> +. + ai * xi". In this case, the first element included in the learning model corresponds to input data (xi) such as x<NUM> and x<NUM>. Further, the weight of the first element corresponds to coefficient ai corresponding to xi. Here, the regression model can be regarded as a simple perceptron having the input layer and the output layer. When each model is regarded as the simple perceptron, the first element can be regarded as any node included in the input layer, and the second element can be regarded as a node included in the output layer.

Furthermore, it is assumed that the learning model according to the present embodiment is realized by the NN including one or more intermediate layers such as a deep neural network (DNN). In this case, the first element included in the learning model corresponds to any node included in the input layer or the intermediate layer. In addition, the second element corresponds to a node of a next stage that is a node to which a value is transmitted from the node corresponding to the first element. In addition, the weight of the first element corresponds to a connection coefficient that is a weight considered for a value transmitted from the node corresponding to the first element to the node corresponding to the second element.

The 3D-LUT for reproducing the color of the developed image of the image obtained by photographing the color sample is calculated using the learning model having an arbitrary structure such as the regression model or the NN described above. More specifically, in the learning model, a coefficient is set so as to output the 3D-LUT for reproducing the color of the image when the developed image of the image obtained by photographing the color sample is input. The learning model according to the present embodiment may be a model generated based on a result obtained by repeating input and output of data.

Note that the above example refers to an example in which the learning model according to the present embodiment is a model (referred to as model A) that outputs the 3D-LUT for reproducing the color of the image when the developed image of the image obtained by photographing the color sample is input. However, the learning model according to the present embodiment may be a model generated based on a result obtained by repeating input and output of data to and from the model A. For example, the learning model according to the present embodiment may be a learning model (referred to as model B) that outputs the 3D-LUT for reproducing the color of the image output by the model A when the developed image of the image obtained by photographing the color sample is input. Still more, the learning model according to the present embodiment may be a learning model that outputs the 3D-LUT for reproducing the color of the image output by the model B when the developed image of the image obtained by photographing the color sample is input.

The estimation unit <NUM> according to the present embodiment inputs the second image obtained by photographing the color sample by the second camera device to the color reproduction LUT estimation model generated by learning the first image obtained by photographing the color sample under the standard light source by the first camera device as the input data and the first 3D-LUT used for developing the first image as the correct answer data, thereby estimating a second 3D-LUT for reproducing the color of the color sample in the second image by the first camera device.

The generation unit <NUM> according to the present embodiment generates a differential 3D-LUT for an adjusted camera device to match its color representation to that of a reference camera device based on a difference between a 3D-LUT of the reference camera device and a 3D-LUT of the adjusted camera device. In addition, the generation unit <NUM> changes 3D-LUT parameters under a predetermined condition to generate the training data for the color reproduction LUT estimation model.

When the number of 3D-LUT parameters (e.g., about <NUM> by <NUM> x <NUM> x <NUM>) estimated by the estimation unit <NUM> is smaller than the number of display colors (e.g., about <NUM> million colors by <NUM> bits of each color of RGB) of the camera device and there is a color that cannot be reproduced, the complementation unit <NUM> according to the present embodiment complements, from the estimated 3D-LUT parameters, a parameter for reproducing the color that cannot be reproduced. A complementation method may be, for example, tetrahedral complementation, polynomial approximation, DNN described above, or the like.

The control unit <NUM> according to the present embodiment is a processing unit that controls the entire information processing apparatus <NUM>, and controls each component included in the information processing apparatus <NUM>. Details of functions of the control unit <NUM> will be described later.

The functional configuration example of the information processing apparatus <NUM> according to the present embodiment has been described above. Note that the functional configuration described above with reference to <FIG> is merely an example, and the functional configuration of the information processing apparatus <NUM> according to the present embodiment is not limited thereto. For example, the information processing apparatus <NUM> may not necessarily include all of the components illustrated in <FIG>, and in a case where learning by the learning model and estimation are performed by different apparatuses, each component such as the estimation unit <NUM> can be included in another apparatus different from the information processing apparatus <NUM>. The functional configuration of the information processing apparatus <NUM> according to the present embodiment can be flexibly modified according to specifications and operations.

In addition, the function of each component may be performed by reading a control program from a storage medium such as a read only memory (ROM) or a random access memory (RAM) storing the control program in which a process procedure for realizing these functions is described by an arithmetic device such as a central processing unit (CPU), and interpreting and executing the program. Therefore, it is possible to appropriately change the configuration to be used according to a technical level at the time of carrying out the present embodiment. Furthermore, an example of a hardware configuration of the information processing apparatus <NUM> will be described later.

Next, functions of the information processing apparatus <NUM> according to the present embodiment will be described in detail. The present embodiment is performed to estimate the 3D-LUT for reproducing, by the first camera device, the color of the image captured by the second camera device different from the first camera device by using the color reproduction LUT estimation model that has learned the image of the color sample photographed by the first camera device such as the smartphone and the 3D-LUT used for developing the image. Therefore, a main process according to the present embodiment is divided into the learning phase and the estimation phase of the color reproduction LUT estimation model. Note that both phases may be executed by the same device or may be executed by different devices.

First, before describing the present embodiment, camera signal processing when a picture is taken by the camera device such as the smartphone will be described.

<FIG> is a diagram illustrating an example of general camera signal processing. <FIG> illustrates various processes executed by an information processing terminal <NUM> such as the smartphone equipped with the camera function. The information processing terminal <NUM> may be a camera device such as a digital camera.

The information processing terminal <NUM> converts light of a subject incident through a camera lens into RAW data <NUM> by an image sensor. In the example in <FIG>, RAW data <NUM> is image data obtained by photographing the color sample, and is signals arranged in a Bayer array by a Bayer filter. The color sample is a color chart including a plurality of colors, such as a Macbeth chart. However, the color sample may also be a chart that includes more colors than the Macbeth chart.

The RAW data <NUM> is adjusted through various correction processes such as linearity correction, noise removal, and light reduction correction, and then converted into full-color image data of RGB signals by demosaic and color matrix processing. Furthermore, in the example in <FIG>, the RGB signals are further converted into YUV (or YCbCr) signals, and developed image data <NUM> is output.

Here, a conversion process using the 3D-LUT for adjusting the color representation of the RAW data <NUM> is generally inserted after a color matrix process or after a conversion process from RGB to YUV signals. Whether to insert the 3D-LUT after either process or both processes depends on the information processing terminal <NUM>. Furthermore, the 3D-LUT to be inserted differs depending on the information processing terminal <NUM>, and the 3D-LUT needs to be generated for each information processing terminal <NUM> (although not necessary to generate from zero, it is necessary to adjust at least the 3D-LUT parameters).

Therefore, in the present embodiment, the 3D-LUT is estimated (generated) using the color reproduction LUT estimation model. Next, the learning phase of the color reproduction LUT estimation model will be described. <FIG> is a diagram illustrating an example of learning of the color reproduction LUT estimation model according to the present embodiment.

A standard light source device <NUM> has a booth shape, and is a device capable of unifying a light source environment by placing a subject in the device even when the subject is photographed in different places. As illustrated in <FIG>, a color sample <NUM> is placed inside the standard light source device <NUM>, and the color sample <NUM> is photographed by the information processing terminal <NUM>. Then, the information processing apparatus <NUM> performs learning of the color reproduction LUT estimation model using a developed image <NUM> of the color sample <NUM> photographed by the information processing terminal <NUM> as the input data and the 3D-LUT (strictly speaking, 3D-LUT data <NUM> of 3D-LUT parameters and the like) used for developing the developed image <NUM> as the correct answer data. Specifically, for example, initial 3D-LUT parameter do not change any color of the developed image <NUM>, and a development process is repeated on the captured image of the color sample <NUM> while changing the parameters according to a predetermined condition, thereby generating a large number of pieces of training data for repetitive learning of the color reproduction LUT estimation model.

Next, the change of the 3D-LUT parameters for generating the training data will be described. <FIG> is a diagram illustrating an example of changing the 3D-LUT parameters according to the present embodiment. As illustrated in <FIG>, a parameter of one piece of 3D-LUT data <NUM>-<NUM> is changed to generate a plurality of pieces of 3D-LUT data <NUM>-<NUM> to <NUM>-n (n is any integer). Note that the parameter of the 3D-LUT data <NUM>-<NUM> is changed, for example, by randomly changing surrounding lattice points as illustrated in <FIG>. Using each of the 3D-LUT data <NUM>-<NUM> to <NUM>-n generated in this manner, the color sample <NUM> photographed by the information processing terminal <NUM> is developed to acquire a plurality of developed images as the training data.

Next, the estimation phase of the color reproduction LUT estimation model will be described. <FIG> is a diagram illustrating an example of estimating the 3D-LUT by the color reproduction LUT estimation model according to the present embodiment. The color reproduction LUT estimation model in <FIG> is the learning model described with reference to <FIG> and learning is performed by using the developed image <NUM> photographed and developed by the information processing terminal <NUM> as the input data and the 3D-LUT data <NUM> used for developing the developed image <NUM> as the correct answer data.

As illustrated in <FIG>, the color sample <NUM> is placed inside the standard light source device <NUM>, and the color sample <NUM> is photographed by a camera device <NUM>. Next, the information processing apparatus <NUM> estimates the 3D-LUT (strictly speaking, 3D-LUT data <NUM>) by inputting developed image <NUM> of the color sample <NUM> photographed by the camera device <NUM> to the color reproduction LUT estimation model.

The 3D-LUT data <NUM> estimated is a 3D-LUT (data) for reproducing, by the information processing terminal <NUM>, the color of the developed image <NUM> photographed by the camera device <NUM>. Therefore, by storing the 3D-LUT data <NUM> in the storage unit of the information processing terminal <NUM> and applying the 3D-LUT data <NUM>, the color of the developed image <NUM> photographed and developed by the camera device <NUM> can be reproduced with the image photographed by the information processing terminal <NUM>.

Next, a procedure for a learning process of the color reproduction LUT estimation model will be described with reference to <FIG> is a flowchart illustrating a flow of the learning process of the color reproduction LUT estimation model according to the present embodiment.

As illustrated in <FIG>, first, the color sample is photographed under the standard light source using a camera device for reproducing color representation of a different camera device (Step S101). A captured image photographed in Step S101 is transmitted to the information processing apparatus <NUM> via various communication networks such as the Internet, a communication cable, and the like.

Next, the acquisition unit <NUM> of the information processing apparatus <NUM> acquires the developed image photographed and developed in Step S101 and the 3D-LUT used for developing the developed image (Step S102).

Next, the learning unit <NUM> of the information processing apparatus <NUM> performs learning of the color reproduction LUT estimation model using the developed image acquired in Step S102 as the input data and the 3D-LUT as the correct answer data (Step S103). After Step S103, the process ends, but the generation unit <NUM> of the information processing apparatus <NUM> changes the 3D-LUT under the predetermined condition and executes Steps S101 to S103 using the changed 3D-LUT, thereby performing repetitive learning of the color reproduction LUT estimation model. As a result, by inputting the image of the color sample photographed and developed by the different camera device to the color reproduction LUT estimation model, it is possible to estimate the 3D-LUT for reproducing the color representation of the different camera device by the camera device used for learning.

Next, a 3D-LUT estimation process by the color reproduction LUT estimation model will be described with reference to <FIG> is a flowchart illustrating a flow of the 3D-LUT estimation process by the color reproduction LUT estimation model according to the present embodiment.

As illustrated in <FIG>, first, the color sample is photographed under the standard light source using a different camera device for reproducing color representation with respect to the camera device used for learning of the color reproduction LUT estimation model (Step S201). A captured image photographed and developed in Step S201 is also transmitted to the information processing apparatus <NUM> via the Internet or the like.

Next, the acquisition unit <NUM> of the information processing apparatus <NUM> acquires the developed image photographed and developed in Step S201 (Step S202).

Next, the estimation unit <NUM> of the information processing apparatus <NUM> inputs the developed image acquired in Step S202 to the color reproduction LUT estimation model and estimates the 3D-LUT (Step S203). After Step S203, the process ends, but by storing the estimated 3D-LUT in the storage unit of the camera device used for learning the color reproduction LUT estimation model and applying the estimated 3D-LUT, it is possible to reproduce color representation of the different camera device used for photographing the image in Step S201.

In addition, it is also possible to correct variations in color representation between camera devices by using the color reproduction LUT estimation model. When camera devices are mass-produced, color representation varies among models even in the same model due to variations in image sensors and the like. Therefore, a reference device serving as a reference is determined from mass-produced camera devices, and the color representation of other devices is adjusted to match the reference device, thereby correcting color representation variations in the same model.

<FIG> is a diagram illustrating an example of correcting color representation variations in the same model using the color reproduction LUT estimation model according to the present embodiment. <FIG> illustrates an example of an adjusted camera device <NUM> adjusted to match the color representation of a reference camera device <NUM> serving as the reference. Here, the reference camera device <NUM> and the adjusted camera device <NUM> are the same model.

As illustrated in <FIG>, the reference camera device <NUM> photographs the color sample <NUM> placed in the standard light source device <NUM>. Then, a developed image <NUM> photographed and developed by the reference camera device <NUM> is input to the color reproduction LUT estimation model to estimate 3D-LUT data <NUM>. Similarly, the adjusted camera device <NUM> photographs the color sample <NUM> placed in the standard light source device <NUM>. Then, a developed image <NUM> photographed and developed is input to the color reproduction LUT estimation model to estimate 3D-LUT data <NUM>.

Next, a differential 3D-LUT is generated by a difference in corresponding parameters of the estimated 3D-LUT data <NUM> and the 3D-LUT data <NUM>. By storing the differential 3D-LUT in the storage unit of the adjusted camera device <NUM> and applying the differential 3D-LUT, the color representation of the adjusted camera device <NUM> can be adjusted to match the color representation of the reference camera device <NUM>. By performing the above process on each of the mass-produced camera devices of the same model as the reference camera device <NUM>, it is possible to correct variations in the color representation in the same model.

Still more, by performing the correction process described with reference to <FIG> on camera devices of different models, one camera device can reproduce color representation of a camera device of a different model. <FIG> is a diagram illustrating an example of color representation matching between different models using the color reproduction LUT estimation model according to the present embodiment. <FIG> illustrates an example of adjusting an adjusted camera device <NUM> to match the color representation of the reference camera device <NUM> serving as the reference. Here, the reference camera device <NUM> and the adjusted camera device <NUM> are different models.

In a process in <FIG>, similarly to <FIG>, each of the reference camera device <NUM> and the adjusted camera device <NUM> photographs the color sample <NUM> placed in the standard light source device <NUM>, and developed images <NUM> and <NUM> photographed and developed are input to the color reproduction LUT estimation model to estimate 3D-LUT data <NUM> and 3D-LUT data <NUM>.

Then, by generating a differential 3D-LUT between the 3D-LUT data <NUM> and the 3D-LUT data <NUM> estimated, storing the differential 3D-LUT in the storage unit of the adjusted camera device <NUM>, and applying the differential 3D-LUT, the color representation of the adjusted camera device <NUM> can be adjusted to match the color representation of the reference camera device <NUM> of a different model.

Next, a hardware configuration example of the information processing apparatus <NUM> according to the present embodiment will be described. <FIG> is a block diagram illustrating a hardware configuration example of the information processing apparatus <NUM> according to the present embodiment. As illustrated in <FIG>, the information processing apparatus <NUM> includes, for example, a processor <NUM>, a ROM <NUM>, a RAM <NUM>, a host bus <NUM>, a bridge <NUM>, an external bus <NUM>, an interface <NUM>, an input device <NUM>, an output device <NUM>, a storage <NUM>, a drive <NUM>, a connection port <NUM>, and a communication device <NUM>. Note that the hardware configuration illustrated here is an example, and some of the components may be omitted. In addition, components other than the components illustrated here may be further included.

The processor <NUM> functions as, for example, an arithmetic processor or a controller, and controls the overall operation of each component or a part thereof based on various programs recorded in the ROM <NUM>, the RAM <NUM>, the storage <NUM>, or a removable recording medium <NUM>.

The ROM <NUM> is a unit that stores a program read by the processor <NUM>, data used for calculation, and the like. The RAM <NUM> temporarily or permanently stores, for example, a program read by the processor <NUM>, various parameters that appropriately change when the program is executed, and the like.

The processor <NUM>, the ROM <NUM>, and the RAM <NUM> are mutually connected via, for example, the host bus <NUM> capable of high-speed data transmission. On the other hand, the host bus <NUM> is connected to the external bus <NUM> having a relatively low data transmission speed via, for example, the bridge <NUM>. In addition, the external bus <NUM> is connected to various components via the interface <NUM>.

As the input device <NUM>, for example, a mouse, a keyboard, a touch panel, a button, a switch, a lever, and the like are used. Furthermore, as the input device <NUM>, a remote controller (hereinafter, remote control) capable of transmitting a control signal using infrared rays or other radio waves may be used. Furthermore, the input device <NUM> includes a voice input device such as a microphone.

The output device <NUM> is a device capable of visually or audibly notifying a user of acquired information, including a display device such as a cathode ray tube (CRT), a liquid crystal display (LCD), or an organic electroluminescence light (EL), an audio output device such as a speaker or a headphone, a printer, a mobile phone, or a facsimile. Furthermore, the output device <NUM> according to the present embodiment includes various vibrating devices capable of outputting tactile stimulation.

The storage <NUM> is a device for storing various types of data. As the storage <NUM>, for example, a magnetic storage device such as a hard disk drive (HDD), a semiconductor storage device, an optical storage device, or a magneto-optical storage device is used.

The drive <NUM> is, for example, a device that reads information recorded on the removable recording medium <NUM> such as a magnetic disk, an optical disk, a magneto-optical disk, or a semiconductor memory, or writes information to the removable recording medium <NUM>.

The connection port <NUM> is a port for connecting an external connection device <NUM> such as a universal serial bus (USB) port, an IEEE <NUM> port, a small computer system interface (SCSI), an RS-<NUM> C port, or an optical audio terminal.

The communication device <NUM> is a communication device for connecting to a network, and is, for example, a communication card for wired or wireless LAN, Bluetooth (registered trademark), or wireless USB (WUSB), a router for optical communication, a router for asymmetric digital subscriber line (ADSL), a modem for various communications, or the like.

The removable recording medium <NUM> is, for example, a DVD medium, a Blu-ray (registered trademark) medium, an HD DVD medium, or various semiconductor storage media. It is obvious that the removable recording medium <NUM> may also be, for example, an IC card on which a non-contact IC chip is mounted or an electronic device.

The external connection device <NUM> is, for example, a printer, a portable music player, a digital camera, a digital video camera, or an IC recorder.

Note that the storage unit <NUM> according to the present embodiment is realized by the ROM <NUM>, the RAM <NUM>, and the storage <NUM>. Furthermore, the control unit <NUM> according to the present embodiment realized by the processor <NUM> reads and executes each control program for realizing the acquisition unit <NUM>, the learning unit <NUM>, the estimation unit <NUM>, the generation unit <NUM>, and the complementation unit <NUM> from the ROM <NUM>, the RAM <NUM>, and the like.

As described above, the information processing apparatus includes the acquisition unit that acquires the second image obtained by photographing the color sample by the second camera device and by developing, and the estimation unit that estimates a second 3D-LUT for reproducing the color of the color sample in the second image by the first camera device by inputting the second image to a model that has learned the first image obtained by photographing the color sample by the first camera device under the standard light source and by developing as the input data and the first 3D-LUT used for developing the first image as the correct answer data.

As a result, the 3D-LUT can be generated more easily.

Although the preferred embodiments of the present disclosure have been described in detail with reference to the accompanying drawings, the technical scope of the present disclosure is not limited to the embodiments. It is obvious that a person having ordinary knowledge in the technical field of the present disclosure can conceive various changes or modifications within the scope of the claims, and it is naturally understood that these also belong to the technical scope of the present disclosure.

Furthermore, the effects described in the present specification are merely illustrative or exemplary, and are not restrictive. In other words, the technology according to the present disclosure can exhibit other effects obvious to those skilled in the art from the description of the present specification in addition to or instead of the above effects.

Claim 1:
A system comprising an information processing apparatus (<NUM>) and an information processing terminal (<NUM>), the information processing apparatus comprising:
an acquisition unit (<NUM>) configured to acquire a second image obtained by photographing a color sample by a second camera device and by developing; and
an estimation unit (<NUM>) configured to estimate a second 3D lookup table, 3D-LUT, for reproducing, by a first camera device, a color of the color sample in the second image by inputting the second image to a model, the model using, for learning, a first image obtained by photographing the color sample under a standard light source (<NUM>) by the first camera device and by developing as input data and a first 3D-LUT used for developing the first image as correct answer data; the information processing terminal comprising:
a storage unit (<NUM>) configured to store the second 3D-LUT estimated by the estimation unit of the information processing apparatus;
and a complementation unit (<NUM>) configured to complement a second parameter with a first parameter for reproducing a color that cannot be reproduced by the second 3D-LUT
when a quantity of the first parameter of the second 3D-LUT is smaller than a number of display colors of the information processing terminal.