KR20210148043A - Loan expansion hypothesis testing system using artificial intelligence and method using the same - Google Patents

Abstract

A loan expansion hypothesis testing system using artificial intelligence is disclosed. The loan expansion hypothesis testing system using artificial intelligence, which is built on the basis of financial data, according to an embodiment of the present invention comprises: an artificial intelligence analysis unit which calculates a default probability value for each of a plurality of financial accounts; a test segment setting unit which classifies the plurality of financial accounts into a plurality of segments based on a predetermined criterion, and sets a specific segment as a test segment to be tested based on the default probability value for each of the plurality of financial accounts, which has been calculated by the artificial intelligence analysis unit; a test group confirmation unit which determines a part of the test segment for an experimental group and a control group for a loan expansion hypothesis test; and a hypothesis test unit which performs the loan expansion hypothesis test on the experimental group and the control group.

Description

LOAN EXPANSION HYPOTHESIS TESTING SYSTEM USING ARTIFICIAL INTELLIGENCE AND METHOD USING THE SAME

The present invention relates to a loan expansion hypothesis testing system using artificial intelligence and a method using the same. More specifically, for a specific financial account group classified based on the default probability value for each financial account, a loan expansion hypothesis testing system using artificial intelligence to test the loan expansion scenario hypothesis using a sample of the specific group, and a system using the same it's about how

If the default risk of a loan is significantly lower, if the loan interest rate is higher than the funding rate, financial institutions handling loan products can always generate profits from the interest rate differential. Accordingly, there is a demand for financial institutions to expand loans to specific groups with low default risk.

Traditionally, in financial institutions such as product design and loan management, policy decisions and risk prediction management of designed loan products were performed by humans. However, the prediction accuracy was not high with the prediction performed by human hands, and there was a problem in that the response to the unexpected variable was not agile. For this reason, risk management through traditional forecasting is somewhat limited.

On the other hand, there is always a demand for financial institutions to expand loans to a group of customers with a low risk of default. This is because, when the customer default risk for a loan is significantly lower and the loan interest rate is higher than the procurement rate, financial institutions handling loan products always generate profits from the interest rate difference. However, even with such demand, it was difficult to accurately select a group of customers with a low risk of bankruptcy with a traditional forecasting system that is performed manually. In addition, financial institutions have a problem in that they have to invest more manpower and consume more finance than before in order to more accurately select a group of customers with a low risk of default by using the traditional method.

KR 10-1799395 B1 (2017. 11. 14.)

The present invention is intended to solve the above problems, and to provide a more reliable solution for selecting a loan expansion target among customers of financial institutions.

In addition, it is intended to provide a test system that can confirm the appropriateness of the group selection for the group subject to loan expansion.

In addition, when a negative result is predicted as a result of the virtual loan expansion policy simulation for the loan expansion target group, it is intended to provide a test system that analyzes the factors affecting the result.

In addition, in the decision-making process such as financial product development, financial product management, execution and account management, it is intended to make more accurate decision-making by using the predictive model of artificial intelligence.

In addition, even without acquiring complex artificial intelligence technology, the financial product manager easily analyzes and simulates the predicted results through artificial intelligence technology and intends to reflect it in the financial product strategy in real time.

The problems to be solved of the present invention are not limited to the above-mentioned contents, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

The loan expansion hypothesis testing system using artificial intelligence built on the basis of financial data according to an embodiment of the present invention is a loan expansion hypothesis testing system using artificial intelligence built on the basis of financial data, and default probability values for a plurality of financial accounts an artificial intelligence analysis unit that calculates ; a test segment setting unit that classifies the plurality of financial accounts into a plurality of segments based on a predetermined criterion, and sets a specific segment as a test segment to be tested based on the default probability value for each of the plurality of financial accounts calculated by the artificial intelligence analysis unit; a test group confirmation unit for determining a part of the test segment for an experimental group and a control group for the loan enlargement hypothesis test; and a hypothesis test unit that performs the loan expansion hypothesis test for the experimental group and the control group.

In addition, the artificial intelligence analysis unit may calculate a default probability value for each of the plurality of financial accounts using a default prediction model generated using machine learning based on the financial data.

Also, the test segment setting unit may set a segment having a minimum average default probability value among the plurality of segments as the test segment.

In addition, the test segment setting unit may be a grade assigned to each of the financial accounts based on the default probability value for each of the plurality of financial accounts as the preset criterion.

In addition, the test segment setting unit merges one or more segments of the plurality of segments into the test segment in the order of the lowest average default probability value of the segment and sets the test segment, but when the test segment approaches a predetermined number of accounts, the merging is stopped can do.

In addition, when it is determined that the test segment has passed the distribution test by setting a preliminary experimental group and a preliminary control group through random sampling and testing the test segment with a distribution test, the test group confirmation unit is determined as the experimental group and the control group, and the distribution test is performed If it is determined that the test did not pass, the distribution test may be re-performed by resampling the preliminary experimental group and the preliminary control group.

In addition, the test group determining unit determines that the distribution test has passed if the difference in the average default probability value of the preliminary experimental group and the preliminary control group is less than or equal to a predetermined value, and the difference in the average default probability value of the preliminary experimental group and the preliminary control group is predetermined If the value is exceeded, it may be determined that the distribution test has not been passed.

In addition, the hypothesis test unit hypothesizes that the future default rate of the experimental group is less than the future default rate of the control group, and sets the null hypothesis that the future default rate of the experimental group is greater than or equal to the future default rate of the control group, and test the null hypothesis To this end, by applying the loan expansion scenario to the experimental group and the existing loan policy maintenance scenario to the control group, the future default probability value for each financial account included in the experimental group and the control group can be predicted using the artificial intelligence analysis unit.

In addition, the loan expansion scenario is one or more of an expansion of a loan amount limit for each financial account, a reduction in an interest rate, and a new loan allowance, and the loan policy maintenance scenario is a loan amount limit applied for each financial account, an interest rate, and a new The loan ban can continue.

In addition, if the average future default probability value of the experimental group is less than the average future default probability value of the control group, the hypothesis test unit determines to reject the null hypothesis, and expands the loan for the entire financial account of the test segment including the control group By applying the same scenario, the loan quality can be measured using the artificial intelligence analysis unit.

In addition, when the average future default probability value of the experimental group is less than the average future default probability value of the control group, the hypothesis test unit determines to reject the null hypothesis, and the second experimental group and the second experimental group in the experimental group through the test group confirmation unit A control group is extracted, a second hypothesis that the future default rate of the second experimental group will be lower than the future default rate of the second control group, and the second null hypothesis that the future default rate of the second experimental group is greater than or equal to the future default rate of the second control group In order to test the second null hypothesis, a second loan expansion scenario in which the loan expansion range is expanded than the loan expansion scenario is applied to the second experimental group, and the existing loan expansion scenario is applied to the second control group. The future default probability value for each financial account of the second experimental group and the second control group may be predicted using the artificial intelligence analysis unit.

In addition, the hypothesis verification unit, if the average future default probability value of the experimental group is greater than or equal to the future average default probability value of the control group, determines to adopt the null hypothesis, and through the artificial intelligence analysis unit A factor may be derived, and the loan expansion test of the loan expansion test system may be re-performed by excluding the one or more financial accounts including the derived main factor.

In addition, the artificial intelligence analysis unit, a financial model generation unit for generating a default prediction model through machine learning (Machine Learning) based on the financial data for each of the plurality of financial accounts; an account management unit for managing a plurality of financial accounts included in the financial products in order to measure the quality of the financial products; a default probability value calculation unit for calculating default probability values for each of the plurality of financial accounts included in the account management unit by using the default prediction model; a quality measurement unit for calculating the quality of the financial product based on the default probability values for each of the plurality of financial accounts calculated by the default probability value calculation unit; and a factor analysis unit that analyzes major factors of the financial account that affect the calculated quality of the financial product, wherein, according to the result of the factor analysis unit, the account management unit selects an account included in the financial product can do.

In addition, if the average future default probability value of the experimental group is greater than or equal to the average future default probability value of the control group, the hypothesis test unit determines to accept the null hypothesis, and the second experimental group and the second experimental group in the experimental group through the test group confirmation unit A control group is extracted, and it is adopted as a second hypothesis that the future default rate of the second experimental group will be lower than the future default rate of the second control group, and that the future default rate of the second experimental group is greater than or equal to the future default rate of the second control group The null hypothesis is set, and to test the second null hypothesis, a second loan expansion scenario in which the loan expansion range is reduced compared to the loan expansion scenario is applied to the second experimental group, and an existing loan expansion scenario is applied to the second control group. By applying the artificial intelligence analysis unit, the future default probability value for each financial account of the second experimental group and the second control group can be predicted.

A loan expansion hypothesis testing method using artificial intelligence built on the basis of financial data according to an embodiment of the present invention includes an artificial intelligence analysis step of calculating a default probability value for each financial account; A test segment setting step of classifying the plurality of financial accounts into a plurality of segments based on a predetermined criterion, and setting a specific segment as a test segment to be tested based on the default probability value for each of the plurality of financial accounts calculated in the artificial intelligence analysis step ; a test group confirmation step of determining an experimental group and a control group for a part of the test segment for the loan enlargement hypothesis test; and a hypothesis test step of performing the loan expansion hypothesis test for the experimental group and the control group.

In addition, the artificial intelligence analysis step may calculate a default probability value for each of the plurality of financial accounts using a default prediction model generated using machine learning based on the financial data.

Also, in the setting of the test segment, a segment having a minimum average default probability value of the segment among the plurality of segments may be set as the test segment.

In addition, in the hypothesis testing step, it is hypothesized that the future default rate of the experimental group will be less than the future default rate of the control group, and the future default rate of the experimental group is greater than or equal to the future default rate of the control group. In order to do so, by applying the loan expansion scenario to the experimental group and the existing loan policy maintenance scenario to the control group, the artificial intelligence analysis step is re-performed to predict the future default probability value for each financial account included in the experimental group and the control group.

In addition, in the hypothesis testing step, if the average future default probability value of the experimental group is less than the average future default probability value of the control group, it is determined that the null hypothesis is rejected, and the loan for the entire financial account of the test segment including the control group Loan quality can be measured by re-performing the AI analysis step by applying the same expansion scenario.

In addition, in the hypothesis verification step, if the average future default probability value of the experimental group is greater than or equal to the future average default probability value of the control group, it is determined that the null hypothesis is adopted, and the main factors of the deterioration of the future average default rate of the experimental group are derived and derived It is possible to re-perform the loan expansion test of the loan expansion test method by excluding the one or more financial accounts including the main factor.

The present invention can provide a more reliable solution for loan expansion hypothesis testing system using artificial intelligence using artificial intelligence and a method using the same according to an embodiment of the present invention to select a loan expansion target among customers of a financial institution.

In addition, with respect to the group subject to loan expansion, the appropriateness of the group selection can be confirmed.

In addition, when a negative result is predicted as a result of a simulation of a virtual loan expansion policy for a loan expansion target group, factors affecting the result can be analyzed.

In addition, in the decision-making process such as financial product development, financial product management, execution and account management, it is possible to make more accurate decisions by using the predictive model of artificial intelligence.

In addition, even without acquiring complex artificial intelligence technology, the financial product manager can easily analyze and predict the results through artificial intelligence technology to simulate the results and reflect them in the financial product strategy in real time.

Effects of the present invention are not limited to the above-mentioned contents, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a block diagram schematically showing a loan expansion hypothesis testing system according to an embodiment of the present invention.
2 is a diagram showing the configuration of an artificial intelligence analysis unit according to an embodiment of the present invention.
3 is a diagram illustrating a data map converted by a data map conversion unit according to an embodiment of the present invention.
4 is a diagram illustrating that the financial product manager assimilation system according to an embodiment of the present invention identifies major factors and re-predicts.
5 is a block diagram schematically illustrating the concept of performing an artificial intelligence analysis unit and a test segment setting unit of a loan expansion hypothesis test system according to an embodiment of the present invention.
6 is a diagram schematically illustrating a flow in which the test group determiner determines the experimental group and the control group according to an embodiment of the present invention.
7 is a diagram schematically illustrating a flow of hypothesis testing by a hypothesis testing unit according to an embodiment of the present invention.
8 is a diagram schematically illustrating a structure performed by a hypothesis testing unit when a null hypothesis is rejected according to an embodiment of the present invention.
9 is a diagram schematically illustrating a structure performed by a hypothesis testing unit when a null hypothesis is adopted according to an embodiment of the present invention.
10 is a flowchart of a loan expansion hypothesis testing method according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art can easily carry out the present invention. However, the present invention may be embodied in several different forms and is not limited to the embodiments described herein. And, in order to clearly describe the embodiment of the present invention in the drawings, parts irrelevant to the description are omitted.

The terms used herein are used only to describe specific embodiments, and are not intended to limit the present invention. The singular expression may include the plural expression unless the context clearly dictates otherwise.

In this specification, terms such as "comprise", "have" or "include" are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, and one It may be understood that it does not preclude the possibility of the presence or addition of or more other features or numbers, steps, operations, components, parts, or combinations thereof.

In addition, the constituent units shown in the embodiment of the present invention are independently shown to represent different characteristic functions, and it does not mean that each constituent unit is composed of separate hardware or one software constituent unit. That is, each component is listed as each component for convenience of description, and at least two components of each component are combined to form one component, or one component can be divided into a plurality of components to perform a function. Integrated embodiments and separate embodiments of each of these components are also included in the scope of the present invention without departing from the essence of the present invention.

In addition, the following embodiments are provided to more clearly explain to those of ordinary skill in the art, and the shapes and sizes of elements in the drawings may be exaggerated for more clear description.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment according to the present invention will be described.

1 is a block diagram schematically showing a loan expansion hypothesis testing system according to an embodiment of the present invention.

Referring to Figure 1, in an embodiment of the present invention, the loan expansion hypothesis test system 10 using artificial intelligence built on the basis of financial data includes an artificial intelligence analysis unit 100, a test segment setting unit 200, It may include a test group determining unit 300 and a hypothesis testing unit 400 .

Here, the financial data may be data related to customers using a financial institution. For example, it may be customers' personal information, credit information, overdue information, and the like.

The artificial intelligence analysis unit 100 may calculate a default probability value for each of the plurality of financial accounts using a default prediction model generated using machine learning based on the financial data. The default prediction model may output, as a result value, the possibility that customers who use the loan product will delay repayment or default on the loan product being used. Hereinafter, the default probability value not only means 'default' in the dictionary definition, but also includes arrears in loan repayment. In addition, since the default prediction model can calculate a default probability value, it may be a 'delinquency prediction model', but for convenience, it will be described as a 'default prediction model'. Accordingly, the default probability model in the claims and specifications of the present invention is not limited to 'default' since it can calculate default probability values or delinquency probability values for each of a plurality of financial accounts. In addition, the ‘delinquency rate’, which will be described later, is also referred to as ‘default rate’ for convenience, but may also include ‘delinquency rate’ in its meaning.

The test segment setting unit 200 classifies the plurality of financial accounts into a plurality of segments based on a predetermined criterion, and a test segment that is a test target for a specific segment based on the default probability value for each of the plurality of financial accounts calculated by the artificial intelligence analysis unit can be set to

The test group determination unit 300 may determine a part of the test segment as an experimental group and a control group for the loan enlargement hypothesis test.

The hypothesis test unit 400 may perform the loan expansion hypothesis test for the experimental group and the control group.

2 is a diagram showing the configuration of an artificial intelligence analysis unit according to an embodiment of the present invention.

Referring to FIG. 2 , the artificial intelligence analysis unit 100 according to an embodiment of the present invention includes a financial model generation unit 110 , an account management unit 120 , a default probability value calculation unit 130 , and a quality measurement unit 140 . and a factor analysis unit 150 . In addition, the artificial intelligence analysis unit 100 may include a data map conversion unit 160 .

The artificial intelligence analysis unit 100 may automatically manage financial products based on the financial data 121 for each of a plurality of financial accounts. Here, the financial data 121 may include internal data 121a collected inside the financial institution or external data 121b collected outside the financial institution.

The internal data 121a may include one or more of personal information, credit information, delinquency information, interest rate information, loan information, income information, debt information, deposit information, and financial transaction information for each account registered with a financial institution. . Personal information may include name, age, age, residence, family relationship, gender, income, workplace, working period, asset status information, etc. Credit information includes credit rating agency rating, internal credit rating, ability to repay, etc. may be included. In addition, delinquency information may include delinquency information about past financial institutions, default information, debt information, etc., and product information such as loan products, loan execution amount, additional interest rate, interest payment amount, balance, etc. may also be included.

The external data 121b refers to data that is not generated by itself inside the bank, and may be collected in a way such as affiliate or scraping. For example, it may be information about a communication company, card usage history, consumption patterns of distribution companies, economic indicators, SNS, interest rates, base rates, and channels in which financial product actions occur. In addition, information such as ratings managed by each securities company and volatility of stocks in a specific period in the past may be included.

The financial model generator 110 may generate the default prediction model 111 through machine learning based on financial data for each financial account.

Here, the machine learning includes a deep neural network (DNN), a convolutional neural network (CNN), a recurrent neural network (RNN), a Restricted Boltzmann Machine (RBM) and deep One or more of a Deep Brief Network (DBN) may be used.

The account manager 120 may manage a plurality of financial accounts input to the generated default prediction model 111 . The account management unit 120 may manage the financial data input to the default prediction model 111 in units of accounts, and may adjust the input accounts. The financial data 121 input to the default prediction model 111 may be managed in units of accounts by the account management unit 120 and input by the quality measurement unit 140 . In addition, in the process of repeating the prediction, the account manager 120 may limit or expand the input range by adjusting the account input to the default prediction model 111 . The account unit may be an account corresponding to one holder, and information included in the account may be classified as a categorical variable to have detailed information. Here, the category may include, for example, nominee, address, gender, repayment method, housing type, balance, loan interest rate, credit information, and the like.

The default probability value calculation unit 130 may calculate default probability values for each of the plurality of financial accounts included in the account management unit 120 using the default prediction model 111 generated by the financial model generation unit 110 . The default probability value calculated by the artificial intelligence analysis unit 100 may be a result value calculated by the default probability value calculation unit 130 .

The quality measurement unit 140 may calculate the quality of the financial product through the default prediction model 111 by inputting financial data for a plurality of financial accounts belonging to the financial product.

The factor analysis unit 150 may analyze major factors of the financial account that affect the quality of the financial product calculated by the quality measurement unit 140 . For example, if the delinquency-default rate is less than 2% for a credit loan product with an interest rate of 5%, if risk management is carried out, the delinquency-default rate prediction result of the future portfolio through the delinquency-default rate prediction model can be up to 3% if risk management is not carried out can be expected to rise. In this case, the factor analysis unit 150 may analyze which major factors need to be adjusted in order to reach the target value of less than 2%. Here, the main factor may be a categorical variable included in the account. And, according to the result of the factor analysis unit 150 , the account management unit 120 may select an account included in the financial product.

The data map conversion unit 160 may visualize the output value of the financial model generating unit 110 or the output value of the quality measuring unit 140 as a vintage chart or a NetFlow chart. Here, a vintage chart or a netflow chart can be referred to as a data map. A data map may be in the form of a graph or table, in which data can be read by humans or machines. The form of the data map may vary depending on the industry applied to the artificial intelligence analysis unit 100 . For example, the data map conversion unit 160 may visualize a data map for an industry such as retail banking using a vintage chart or a netflow chart, and a different type of data map for a business such as a securities company and credit card.

3 is a diagram illustrating a data map converted by a data map conversion unit according to an embodiment of the present invention.

Referring to FIG. 3 , the output value of the quality measuring unit 140 may be visualized as a vintage chart or a Netflow chart. The vintage chart is an analysis index created to compare portfolios executed in a specific period (January, February, 2017, etc.), and is similar to an index that manages the quality of each vintage of wine. The chart of FIG. 3 is a chart showing the cumulative record of Ever 5+, that is, an account that is expected to be delinquent for more than 5 days at least once.

Referring to FIG. 3, for example, out of 12,423 accounts executed in January 2017, the proportion (L1) of accounts that are expected to be delinquent for at least 5 days during 25 months after loan execution is about 25%. 3,106 accounts. These forecast data are accumulated over time and displayed, and a graph of each executed monthly portfolio can be drawn. If the graph of the monthly portfolio is referred to as quality, the chart converted by the data map conversion unit 160 may include the target quality L0. If the predicted quality L1 at the same time point is similar to the target quality L0, the quality of the predicted loan portfolio can be evaluated as good. Such quality may include one or more of yield, default rate, or prepayment rate.

The types of data maps that can be generated by the data map conversion unit 160 according to the present invention and the types of graphs visualized by combining them with a predictive model can be generated in various categories, and can be generated from a number of variable axes, not just a two-dimensional graph. Branches may also include multidimensional graphs.

For example, 50 out of 1000 accounts are delinquent. And if an additional 2,000 accounts are issued new loans in the next month, the delinquency rate may be lowered to 50/3000 because the newly issued accounts do not have delinquency. As such, the delinquency rate is not a problem that can be determined with only one indicator, so it can be expressed using a multidimensional axis.

The factor analysis unit 150 determines whether the predicted quality L1 is good or bad compared to the target quality L0. As for the standard of good quality, the difference d1 between the values of the quality L1 and the target quality L0 predicted at the same time point is calculated, and when the difference d1 is less than a certain standard, it can be determined that the quality is good. In addition, when it is determined that the predicted quality L1 is not good, the factor analysis unit 150 determines a major factor capable of reducing the difference d1 from the target quality L0, and analyzes the influence of the major factor. can

Here, the main factor is that the numerical value of the detailed information of the category included in the account, which is the input data of the default prediction model 111 generated by the financial model generation unit 110, is limited or the account including the specific category information is used for loan execution. Inclusion or limitation may be the one that can bring about the greatest change in the difference d1.

For example, the first account, the second account, and the third account may be input as accounts input to the default prediction model 111 . The first account, the second account, and the third account are accounts in which the loan was executed at the time 'A'. The category for each account may include 'delinquency history'. Here, 'delinquency history' means being overdue for more than 5 days before the relevant point in time, and the detailed information of the scope of 'delinquency history' may be counting the history of delinquency of each account in the past according to the above criteria. And if the detailed information of the category of the 'delinquency history' of the second account is '3' or more, the factor analysis unit 150 returns the account except for the account with a value of '1' or more in the category of the 'delinquency history' When the difference d1 is reduced by input to the default prediction model 111, it is possible to determine the 'delinquency history' as a major factor.

4 is a diagram illustrating that the financial product manager assimilation system according to an embodiment of the present invention identifies major factors and re-predicts.

Referring to FIG. 4 , the factor analysis unit 150 can determine not only the just-described 'delinquency history' but also a very diverse and redundant main factor. In the default prediction model 111, not one model is generated, but various models having output values according to each purpose may be generated. In addition, the factor analysis unit 150 may calculate various prediction graphs using values predicted by one default prediction model 111 . 4 shows the default prediction model 111 predicts the monthly delinquency rate according to the inputted accounts, and the quality measurement unit 140 calculates the cumulative default rate according to the predicted monthly delinquency rate and calculates the ratio of the accounts going bankrupt within 3 months Therefore, it is shown that they are classified on a scale of 1 to 10.

3 and 4, when the factor analysis unit 150 determines that the main factor for reducing the difference d1 between the predicted quality L1 and the target quality L0 is 'delinquency history', the account management unit 120 can exclude accounts with 'delinquency history' from the input account data. The quality measurement unit 140 may calculate the default rate by using the default prediction model 111 re-entered into the account excluding the 'delinquency history', and the data map conversion unit 160 is Based on the calculated value, the cumulative default rate can be output again. In this case, the difference d2 between the predicted quality L2 and the target quality L0 may be reanalyzed. If it is not determined that the quality is good, the factor analysis unit 150 may analyze the main factors again. At this time, if the factor analysis unit 150 determines that an account that has received a grade of 10 in the ratio of defaulted accounts within 3 months is a major factor, the account management unit 120 classifies it into 10 grades among accounts input to the default prediction model 111 . It can be input to the default prediction model 111 except for the account again. The artificial intelligence analysis unit 100 may repeat this process and calculate the predicted quality L3 determined to be of good quality.

The account management unit 120 extracts one or more accounts that satisfy the criterion for the main factor from among the plurality of account information, and a post action unit that recommends an action to be taken to the account holder and another account that satisfies the criterion for the main factor It may include a pre-action unit that prohibits a loan for

Here, an action is an action taken by the user. For example, if the main factor is determined to be level 10, it is an action such as calling, sending an e-mail, or confiscation of assets to the holder of an account classified as level 10. can recommend The pre-action unit may exclude accounts similar to those classified in the tenth grade among loan candidate accounts whose main factor is to issue loans in the future.

5 is a block diagram schematically illustrating the concept of performing an artificial intelligence analysis unit and a test segment setting unit of a loan expansion hypothesis test system according to an embodiment of the present invention.

Referring to FIG. 5 , in an embodiment of the present invention, the artificial intelligence analysis unit 100 may calculate a default probability value for the financial account data 122 . The financial account data 122 may be group data including a plurality of financial account data. As described in FIG. 2 , the artificial intelligence analysis unit 100 uses the default prediction model 111 generated by machine learning the financial data 121 for each financial account data included in the financial account data 122 . Each default probability value can be calculated.

The test segment setting unit 200 classifies the financial account data 122 into a plurality of segments 123 based on a predetermined criterion, and based on the default probability value for each financial account data calculated by the artificial intelligence analysis unit 100, a specific The segment may be set as the test segment 124 to be tested. An average default probability value of each segment 123 may be calculated for the plurality of segments 123 , and a segment having a minimum average default probability value among the calculated average default probability values of the segments 123 may be set as the test segment 124 .

More specifically, the test segment setting unit 200 may assign a grade to each financial account data based on the default probability value for each financial account data. As an example, a lower grade may be assigned to follow a uniform distribution or a normal distribution by arranging default probability values in order of magnitude. For example, if it is 0% to 10%, it can be given as 1st grade, if it is 11% to 20%, it can be given as 2nd grade, and if it is 21% to 30%, it can be given as 3rd grade. In this case, a grade from grade 1 to grade 10 may be assigned. A plurality of segments 123 may be classified for each grade, and a segment having the lowest grade, that is, a segment having the smallest average default probability value of the segment, may be set as the test segment 124 . Here, the predetermined criterion may be a grade assigned to each financial account data.

In addition, according to the embodiment, the preset criteria are [type of loan product (A/B/C)], [age (20s/30s/40s/50s/60s)], [gender (male/ female)], etc., the preset criteria are not specified as any one, and may be changed at any time according to the user's designation. In addition, the preset criterion may be applied to one or more rather than one. For example, the predetermined criteria may be specified as [type of loan product & age group (A&30s)] or [type of loan product & age group & gender (B&40s & female)]. The test segment setting unit 200 calculates the segment 123 average default probability value based on the default probability value for each financial account data for a plurality of segments 123 classified according to the preset criteria, and calculates the lowest average default probability value. The branch 123 may be set as the black segment 124 .

In addition, the black segment setting unit 200 may classify the plurality of segments 123 according to all of the pre-specified criteria that can be designated. That is, the segment 123 may be classified according to all labels included in the financial account data. For example, the test segment setting unit 200 may classify the segment 123 into all divisible criteria such as gender, age, loan product, region, and the like.

In this case, the test segment setting unit 200 may set the segment 123 having the lowest average default probability value among the classified segments 123 as the test segment 124 , or set one or more segments 123 to the segment 123 . ) of the average default probability values are merged in descending order, but when the number of financial accounts included in the merged segment 123 reaches or approaches a preset number of accounts, the merging is stopped, and the merged segments 123 up to this point are merged. Black segment 124 can be set. For example, if there are 100 accounts on average in one segment 123 and the preset number of accounts is 1,000 accounts, a plurality of segments 123 in the order of lower average default probability to approximate 1000 accounts are evaluated as the test segment 124 . ) can be set.

6 is a diagram schematically illustrating a flow in which the test group determiner determines the experimental group and the control group according to an embodiment of the present invention.

Referring to FIG. 6 , the test group determiner 300 may extract an experimental group and a control group for testing a hypothesis with respect to the test segment 124 . The test group determiner 300 may extract the preliminary experimental group 125 and the preliminary control group 126 from the set test segment 124 through random sampling. The test group determiner 300 may perform a distribution test on the set preliminary experimental group 125 and the preliminary control group 126 . Here, the distribution test may be a Mann-Whitney test. When it is determined that the set preliminary experimental group 125 and the preliminary control group 126 have passed the distribution test, the test group confirmation unit 300 sets the preliminary experimental group 125 and the preliminary control group 126 to the confirmed experimental group 127 and the definitive control group. (128) can be confirmed. When it is determined that the set preliminary experimental group 125 and the preliminary control group 126 do not pass the distribution test, the test group confirmation unit 300 re-performs random sampling to reset the preliminary experimental group 125 and the preliminary control group 126 . Thus, the distribution test can be re-performed. The criterion for passing the distribution test is that if the difference in the average probability of default between the preliminary experimental group and the preliminary control is less than or equal to a predetermined value, it is determined that the distribution test has passed, and the difference in the average probability of default between the preliminary experimental group and the preliminary control is previously If it exceeds a predetermined value, it may be determined that the distribution test has not been passed.

7 is a diagram schematically illustrating a flow of hypothesis testing by a hypothesis testing unit according to an embodiment of the present invention.

7, in one embodiment of the present invention, the hypothesis testing unit 400 hypothesizes that the future default rate of the experimental group will be less than the future default rate of the control group, and that the future default rate of the experimental group is greater than or equal to the future default rate of the control group It can be set to the null hypothesis. Here, the experimental group or the control group is the same as the definitive experimental group 127 or the definitive control group 128 confirmed by the test group determining unit 300 of FIG. 6 . Hereinafter, the experimental group or the control group for which the hypothesis test is performed will be described as a definitive experimental group 127 or a definitive control group 128 . The hypothesis tested by the hypothesis testing unit 400 may be to verify the null hypothesis in which the future default rate of the aforementioned confirmed experimental group 127 is greater than or equal to the future default rate of the definitive control group 128 . The 'hypothesis rejection' or 'hypothesis acceptance' due to the test of the hypothesis testing unit 400 means 'rejection' or 'acceptance' of the null hypothesis.

The hypothesis test unit 400 applies the loan expansion scenario to the experimental group and the existing loan policy maintenance scenario to the control group to test the null hypothesis, and uses the artificial intelligence analysis unit to determine the experimental group 127 and the definitive control group 128 ), it is possible to predict the future default probability value for each financial account included in the .

Here, the loan expansion scenario may be one or more of an expansion of a loan amount limit for each financial account, a reduction in an interest rate, and a new loan allowance, and the loan policy maintenance scenario includes a loan amount limit applied for each financial account, an interest rate, and It could be that the ban on new lending continues.

The hypothesis testing unit 400 determines that the null hypothesis is rejected if the average future default probability value of the definitive experimental group 127 is less than the future average default probability value of the definitive control group 128, and the future average default of the definitive experimental group 127 If the probability value is equal to or greater than the average future default probability value of the definitive control group 128 , it may be determined that the null hypothesis is accepted. In this case, the hypothesis testing unit 400 may test through the Z-Test.

인 이항모집단으로부터 크기가

인 확률표본에 의해 정의되는 표본비율을

이라 하고, 이와 독립적으로 모비율이

인 이항모집단으로부터 크기가

인 확률표본에 의해 정의되는 표본비율을

라고 하면, 표본크기

과

가 충분히 큰 경우, 가설에 대한 검정 통계량

는 수학식 1과 같을 수 있다.More specifically, the mother ratio (parent delinquency ratio) is

From a binomial population of

The sample proportion defined by the probability sample of

, and independently of this, the mother ratio is

From a binomial population of

The sample proportion defined by the probability sample of

, the sample size

class

is large enough, the test statistic for the hypothesis

may be equal to Equation 1.

는 수학식 2와 같다.Here, in Equation 1

is the same as in Equation 2.

은 확정 실험군(127)의 표본 수,

는 확정 대조군(128)의 표본 수,

는 확정 실험군(127)의 모비율(모 부도율),

는 확정 대조군(128)의 모비율(모 부도율),

는 확정 실험군(127)의 표본비율(표본 부도율),

는 확정 대조군(128)의 표본비율(표본 부도율)일 수 있다.In one embodiment of the present invention,

is the number of samples in the definitive experimental group (127),

is the number of samples in the definitive control (128),

is the ratio of mothers (parental failure rate) of the confirmed experimental group (127),

is the proportion of mothers (parental failure rate) of the definitive control group (128),

is the sample rate (sample default rate) of the confirmed experimental group (127),

may be the sample rate (sample default rate) of the definitive control group 128 .

Also, the null hypothesis may be Equation (3).

은 귀무가설일 수 있으며, 그 내용은 확정 실험군(127)의 미래 부도율이 확정 대조군(128)의 미래 부도율 이상일 수 있다. 즉, 확정 실험군(127)은 상기 대출 확대 시나리오에서 부도율이 더 악화된다는 것일 수 있다.here,

may be a null hypothesis, and the content may indicate that the future default rate of the definitive experimental group 127 may be greater than or equal to the future default rate of the definitive control group 128 . That is, in the confirmed experimental group 127, the default rate may be worse in the loan expansion scenario.

The approximate rejection range of the null hypothesis may be Equation (4).

은 근사기각역일 수 있으며, 주어진 유의수준

값에 대하여

는 검정통계량

의 분포가

을 따를 때,

를 만족시키는 값일 수 있다. 수학식 4를 만족하는 경우, 가설 검정부(400)는 귀무가설을 기각한다는 판단을 할 수 있다.here,

can be in the approximate rejection range, given the significance level

about the value

is the test statistic

the distribution of

When following

may be a value that satisfies When Equation 4 is satisfied, the hypothesis testing unit 400 may determine to reject the null hypothesis.

The user can check the simulation results of the confirmed experimental group 127 and the definitive control group 128 through the visual data 161 provided by the data map conversion unit 160 of the artificial intelligence analysis unit 100 . Through this, it is possible to confirm the change in risk by not only checking the result, but also by checking the time-series trend of default rates.

8 is a diagram schematically illustrating a structure performed by a hypothesis testing unit when a null hypothesis is rejected according to an embodiment of the present invention.

Referring to Figure 8 (a), in one embodiment of the present invention, when the hypothesis test unit 400 determines to reject the null hypothesis, the hypothesis test unit 400 is applied to the confirmation experimental group 127 the loan The amplification scenario is equally applicable for the test segment including the definitive control 128 . The fact that the hypothesis testing unit 400 rejected the null hypothesis means that the loan quality of the confirmed experimental group 127 was better than that of the confirmed control group 128. have.

Referring to FIG. 8( b ), in an embodiment of the present invention, when the hypothesis testing unit 400 determines to reject the null hypothesis, the hypothesis testing unit 400 is confirmed through the test group determination unit 300 . A second confirmed experimental group 127a and a second confirmed control group 128a may be extracted from the experimental group 127 . The hypothesis test unit 400 applies the second loan expansion scenario in which the loan expansion range is expanded than the loan expansion scenario to the second confirmed experimental group 127a, and the existing loan expansion scenario is applied to the second confirmed control group 128a. can At this time, the hypothesis testing unit 400 sets the second hypothesis that the future default rate of the second confirmed experimental group 128a will be lower than the future default rate of the second confirmed control group 128a. 2 The second null hypothesis may be set to be greater than or equal to the future default rate of the definitive control group 128a, and hypothesis testing may be performed again to verify the second null hypothesis. When the hypothesis test for verifying the second null hypothesis is re-performed, an artificial intelligence analysis unit may be used to predict the future default probability value for each financial account of the second experimental group and the second control group and utilize it. In the limited experimental group, the experimental group and the control group are again classified and verified by applying a more expanded loan expansion scenario to determine the maximum point at which loan expansion is possible, and hypothesis testing can be performed again until this point can be determined. . For example, if there is a stage in which a hypothesis is adopted during the iteration of hypothesis testing, it may be determined that the stage is the maximum point at which loan expansion is possible.

9 is a diagram schematically illustrating a structure performed by a hypothesis testing unit when a null hypothesis is adopted according to an embodiment of the present invention.

Referring to FIG. 9( a ), in an embodiment of the present invention, when the hypothesis testing unit 400 determines to accept the null hypothesis, the hypothesis testing unit 400 performs the artificial intelligence analysis unit 100 through the The main factors for the deterioration of the future average default rate of the experimental group can be derived. In addition, the hypothesis test unit 400 may re-perform the loan expansion test of the loan expansion test system except for the one or more financial accounts including the derived main factors. That is, the artificial intelligence analysis unit 100 may determine that the learned default prediction model is wrong. And the artificial intelligence analysis unit 100 may regenerate the default prediction model by changing the hyperparameter or excluding one or more financial accounts including the main factor from the learning data. After that, the loan expansion hypothesis testing system can perform the analysis again from the beginning using the new default prediction model.

Referring to FIG. 9( b ), in an embodiment of the present invention, when the hypothesis testing unit 400 determines to accept the null hypothesis, the hypothesis testing unit 400 determines the experimental group through the test group determination unit 300 . A second definitive experimental group 127b and a second definitive control group 128b may be extracted from within (127). The hypothesis testing unit 400 may apply a second loan expansion scenario in which the loan expansion range is reduced compared to the loan expansion scenario to the second confirmed experimental group 127b, and the existing loan policy maintenance scenario to the second confirmed control group 128a. have. At this time, the hypothesis testing unit 400 assumes that the future default rate of the second confirmed experimental group 128b will be lower than the future default rate of the second confirmed control group 128b. 2 The second null hypothesis may be set to be equal to or greater than the future default rate of the definitive control group 128b, and hypothesis testing to verify the second null hypothesis may be performed again. When the hypothesis verification for verifying the second null hypothesis is performed again, the future default probability value for each financial account of the second confirmed experimental group 127a and the second confirmed experimental group 127a is predicted by using the artificial intelligence analysis unit 100. can be used In the limited experimental group, it seems that the default prediction model generated by learning the artificial intelligence analysis unit 100 is appropriate to classify the experimental group and the control group and apply the reduced loan expansion scenario, but the loan expansion range of the loan expansion scenario is This may be to determine the maximum point at which loan expansion is possible, judging that it was large. Therefore, the hypothesis test can be re-performed until this point can be determined. For example, if there is a stage in which a hypothesis is adopted during the iteration of hypothesis testing, it may be determined that the stage is the maximum point at which loan expansion is possible.

Before applying the loan product to the actual market, the loan expansion hypothesis testing system according to an embodiment of the present invention may identify an appropriate customer reference group and major factors to handle the loan product. In addition, risks can be identified in advance through virtual simulation and time-series risk change trends can be checked, thereby facilitating risk control. In addition, it is possible to prevent mistakes and errors that may occur when a human performs, and the execution cost can be significantly reduced. This will enable financial institutions to make more accurate and quick decisions on how to handle loan products.

10 is a flowchart of a loan expansion hypothesis testing method according to an embodiment of the present invention.

* Referring to FIG. 10, in one embodiment of the present invention, the loan expansion hypothesis test method using artificial intelligence built on the basis of financial data is an artificial intelligence analysis step (S100), a test segment setting step (S200), a test It may include a group determination step (S300) and a hypothesis testing step (S400).

The artificial intelligence analysis step ( S100 ) may calculate a default probability value for each of a plurality of financial accounts.

The test segment setting step (S200) classifies the plurality of financial accounts into a plurality of segments based on a predetermined criterion, and tests a specific segment as a test target based on the default probability value for each of the plurality of financial accounts calculated in the artificial intelligence analysis step Segments can be set.

The test group confirmation step (S300) may determine an experimental group and a control group for the loan enlargement hypothesis test for a part of the test segment.

The hypothesis test step (S400) may perform the loan expansion hypothesis test for the experimental group and the control group. The artificial intelligence analysis step S100 may calculate default probability values for each of the plurality of financial accounts using a default prediction model generated using machine learning based on the financial data.

The test segment setting step ( S200 ) may set a segment having a minimum average default probability value among the plurality of segments as the test segment.

In the hypothesis testing step (S400), it is hypothesized that the future default rate of the experimental group will be less than the future default rate of the control group, and the future default rate of the experimental group may be greater than or equal to the future default rate of the control group as a null hypothesis. To test the null hypothesis, the artificial intelligence analysis step is re-performed by applying the loan expansion scenario to the experimental group and the existing loan policy maintenance scenario to the control group, and the future default probability value for each financial account included in the experimental group and the control group can be predicted.

In addition, in the hypothesis testing step ( S400 ), if the average future default probability value of the experimental group is less than the average future default probability value of the control group, it may be determined that the null hypothesis is rejected. Loan quality may be measured by re-performing the AI analysis step by applying the loan expansion scenario to the entire financial account in the test segment including the control group.

In addition, in the hypothesis testing step ( S400 ), if the average future default probability value of the experimental group is equal to or greater than the average future default probability value of the control group, it may be determined that the null hypothesis is adopted. It is possible to derive the main factors of the deterioration of the future average default rate of the experimental group, and re-perform the loan expansion test of the loan expansion test method by excluding the one or more financial accounts including the derived major factors.

The various embodiments described in the specification may be implemented by hardware, middleware, microcode, software, and/or combinations thereof. For example, various embodiments may include one or more application specific semiconductors (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field programmable gate arrays (FPGAs). ), processors, controllers, microcontrollers, microprocessors, other electronic units designed to perform the functions presented herein, or a combination thereof.

Also, for example, the various embodiments may be embodied in or encoded on a computer-readable medium comprising instructions. The instructions embodied in or encoded on a computer-readable medium may cause a programmable processor or other processor to perform a method, eg, when the instructions are executed. Computer-readable media includes both computer storage media and communication media including any medium that facilitates transfer of a computer program from one place to another. A storage medium may be any available medium that can be accessed by a computer. For example, such computer-readable medium may include RAM, ROM, EEPROM, CD-ROM or other optical disk storage medium, magnetic disk storage medium or other magnetic storage device or desired program code, instructions or data accessible by a computer. may include any other medium that can be used for transporting or storing in the form of structures.

Such hardware, software, firmware, etc. may be implemented in the same device or in separate devices to support the various operations and functions described herein. Additionally, components, units, modules, components, etc. described as “parts” in the present invention may be implemented together or individually as separate but interoperable logic devices. Depictions of different features of modules, units, etc. are intended to emphasize different functional embodiments, and do not necessarily imply that they must be realized by separate hardware or software components. Rather, functionality associated with one or more modules or units may be performed by separate hardware or software components or integrated within common or separate hardware or software components.

Although acts are shown in the drawings in a particular order, it should not be understood that these acts need to be performed in the specific order, or sequential order, shown, or that all shown acts need to be performed to achieve a desired result. . In certain circumstances, multitasking and parallel processing may be advantageous. Moreover, the division of various components in the above-described embodiments should not be construed as requiring such division in all embodiments, and that the described components will generally be integrated together into a single software product or packaged into multiple software products. It should be understood that there can be

Although the present invention has been described with reference to the embodiment shown in the drawings, which is merely exemplary, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

10: Loan expansion hypothesis testing system 100: Artificial intelligence analysis unit
110: financial model generation unit 120: account management unit
130: default probability value calculation unit 140: quality measurement unit
150: factor analysis unit 160: data map conversion unit
200: test segment setting unit 300: test group confirmation unit
400: hypothesis test unit

Claims (18)

In the loan expansion hypothesis testing system using artificial intelligence built on the basis of financial data,
an artificial intelligence analysis unit that calculates default probability values for each of a plurality of financial accounts;
a test segment setting unit that classifies the plurality of financial accounts into a plurality of segments based on a predetermined criterion, and sets a specific segment as a test segment to be tested based on the default probability value for each of the plurality of financial accounts calculated by the artificial intelligence analysis unit;
a test group confirmation unit for determining a part of the test segment for an experimental group and a control group for the loan enlargement hypothesis test; and
Loan expansion hypothesis testing system comprising a; hypothesis test unit for performing the loan expansion hypothesis test for the experimental group and the control group.
According to claim 1,
The artificial intelligence analysis unit,
Loan expansion hypothesis testing system that calculates default probability values for each of the plurality of financial accounts using a default prediction model generated using machine learning based on the financial data.
According to claim 1,
The black segment setting unit,
Loan expansion hypothesis testing system for setting a segment having the smallest average default probability value among the plurality of segments as the test segment.
4. The method of claim 3,
The black segment setting unit,
The predetermined criterion is a loan expansion hypothesis testing system that is a rating given to each financial account based on the default probability value for each of the plurality of financial accounts.
According to claim 1,
The black segment setting unit,
One or more segments among the plurality of segments are merged into the test segment in the order of the lowest average default probability value of the segment and set,
When the test segment approaches a predetermined number of accounts, the loan expansion hypothesis test system will stop the merging.
According to claim 1,
The test group confirmation unit,
When it is determined that the test segment has passed the distribution test by setting a preliminary experimental group and a preliminary control group through random sampling and testing it with a distribution test, it is confirmed as the experimental group and the control group,
If it is determined that the distribution test did not pass, the loan expansion hypothesis test system that re-sampling the preliminary experimental group and the preliminary control group to re-perform the distribution test.
7. The method of claim 6,
The test group confirmation unit,
If the difference between the average default probability value of the preliminary experimental group and the preliminary control group is less than or equal to a predetermined value, it is determined that the distribution test has been passed,
If the difference between the average default probability value of the preliminary experimental group and the preliminary control group exceeds a predetermined value, it is determined that the distribution test has not been passed.
According to claim 1,
The hypothesis test unit,
A hypothesis is set that the future default rate of the experimental group is less than the future default rate of the control group, and the null hypothesis is set that the future default rate of the experimental group is greater than or equal to the future default rate of the control group,
In order to test the null hypothesis, a loan expansion scenario is applied to the experimental group and an existing loan policy maintenance scenario is applied to the control group, and the future default probability value for each financial account included in the experimental group and the control group is predicted using the artificial intelligence analysis unit. Loan expansion hypothesis testing system.
9. The method of claim 8,
The loan expansion scenario is one or more of the expansion of the loan amount limit for each financial account, the reduction of the interest rate, and the permitting of new loans;
The loan policy maintenance scenario is a loan expansion hypothesis testing system that continuously maintains the loan amount limit, interest rate, and new loan ban applied for each financial account.
9. The method of claim 8,
The hypothesis test unit,
If the average future default probability value of the experimental group is less than the average future default probability value of the control group, it is determined that the null hypothesis is rejected;
Loan expansion hypothesis testing system to measure loan quality using the artificial intelligence analysis unit by applying the loan expansion scenario to the entire financial account of the test segment including the control group.
9. The method of claim 8,
The hypothesis test unit,
If the average future default probability value of the experimental group is less than the average future default probability value of the control group, it is determined that the null hypothesis is rejected;
A second experimental group and a second control group are extracted from the experimental group through the test group confirmation unit, and the second hypothesis that the future default rate of the second experimental group will be lower than the future default rate of the second control group, the future of the second experimental group The second null hypothesis is set that the default rate is greater than or equal to the future default rate of the second control group,
In order to test the second null hypothesis, a second loan expansion scenario in which the loan expansion range is expanded than the loan expansion scenario is applied to the second experimental group, and the existing loan expansion scenario is applied to the second control group to analyze the AI Loan expansion hypothesis testing system to predict the future default probability value for each financial account of the second experimental group and the second control group using wealth.
9. The method of claim 8,
The hypothesis test unit,
If the average future default probability value of the experimental group is greater than or equal to the future average default probability value of the control group, it is determined that the null hypothesis is adopted,
Deriving the main factors of the deterioration of the future average default rate of the experimental group through the artificial intelligence analysis unit, excluding one or more of the financial accounts containing the derived main factors, and re-performing the loan expansion test of the loan expansion test system Loan expansion hypothesis testing system.
13. The method of claim 12,
The artificial intelligence analysis unit,
a financial model generator for generating a default prediction model through machine learning based on the financial data for each of the plurality of financial accounts;
an account management unit for managing a plurality of financial accounts included in the financial products in order to measure the quality of the financial products;
a default probability calculation unit for calculating default probability values for each of the plurality of financial accounts included in the account management unit by using the default prediction model;
a quality measurement unit for calculating the quality of the financial product based on the default probability values for each of the plurality of financial accounts calculated by the default probability value calculation unit; and
Including; a factor analysis unit for analyzing major factors of the financial account that affect the calculated quality of the financial product;
Based on the result of the factor analysis unit, the account management unit is a loan expansion hypothesis testing system that selects the accounts included in the financial products.
9. The method of claim 8,
The hypothesis test unit,
If the average future default probability value of the experimental group is greater than or equal to the future average default probability value of the control group, it is determined that the null hypothesis is adopted,
A second experimental group and a second control group are extracted from the experimental group through the test group confirmation unit, and the second experimental group is adopted as a second hypothesis that the future default rate of the second experimental group will be lower than that of the second control group, and the second experimental group The second null hypothesis is set that the future default rate of is greater than or equal to the future default rate of the second control group,
In order to test the second null hypothesis, a second loan expansion scenario in which the loan expansion range is reduced compared to the loan expansion scenario is applied to the second experimental group, and the existing loan expansion scenario is applied to the second control group to analyze the AI Loan expansion hypothesis testing system to predict the future default probability value for each financial account of the second experimental group and the second control group using wealth.
In the loan expansion hypothesis test method using artificial intelligence built on the basis of financial data,
an artificial intelligence analysis step of calculating default probability values for each of a plurality of financial accounts;
A test segment setting step of classifying the plurality of financial accounts into a plurality of segments based on a predetermined criterion, and setting a specific segment as a test segment to be tested based on the default probability value for each of the plurality of financial accounts calculated in the artificial intelligence analysis step ;
a test group confirmation step of determining an experimental group and a control group for a part of the test segment for the loan enlargement hypothesis test; and
A hypothesis testing step of performing the loan expansion hypothesis test for the experimental group and the control group; loan expansion hypothesis testing method comprising a.
16. The method of claim 15,
The artificial intelligence analysis step is,
Loan expansion hypothesis testing method for calculating the default probability value for each of the plurality of financial accounts using a default prediction model generated using machine learning based on the financial data.
16. The method of claim 15,
The black segment setting step is
Loan expansion hypothesis testing method of setting a segment having the minimum average default probability value of the segment among the plurality of segments as the test segment.
16. The method of claim 15,
The hypothesis testing step is,
A hypothesis is set that the future default rate of the experimental group is less than the future default rate of the control group, and the null hypothesis is set that the future default rate of the experimental group is greater than or equal to the future default rate of the control group,
To test the null hypothesis, the artificial intelligence analysis step is re-performed by applying the loan expansion scenario to the experimental group and the existing loan policy maintenance scenario to the control group, and the future default probability value for each financial account included in the experimental group and the control group A method of testing the loan expansion hypothesis that predicts

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