CN110444296B - Three-dimensional color block obstacle testing system, storage medium, device and implementation method - Google Patents

Abstract

The invention provides a three-dimensional color block obstacle testing system, a storage medium, a device and an implementation method, wherein the three-dimensional color block obstacle testing system comprises: the information input unit is used for recording the information of the test object; the test unit comprises a mirror image test module and a task test module and is used for the practice and the test of the test object on the test task; the data analysis unit is used for receiving and analyzing the task test data to obtain a test result; and the file storage unit is used for receiving and storing the information, the test data and the test result of the test object and outputting the test result. The device and the implementation method can provide a simpler, more convenient and more accurate unilateral finger flexibility test method for diagnosis, treatment and rehabilitation of diseases such as mild cognitive dysfunction, senile dementia and the like.

Description

Three-dimensional color block obstacle testing system, storage medium, device and implementation method

Technical Field

The invention relates to the field of signal processing, human-computer interaction and pervasive computing, in particular to an electronic three-dimensional color block obstacle testing system.

Background

The three-dimensional color Block obstacle Test (BBT) is a quick, simple, and low-cost one-sided finger flexibility Test, and can evaluate the flexibility of fingers, and the structure diagram is shown in fig. 1, in which a three-dimensional color Block refers to a three-dimensional Block with the same color on each outer surface, and is similar to a building Block Box. Jean Hyres, Patricia Buhler et al, in 1957, proposed an initial version of BBT: e.fuchs, p.buhler, et al, perfected BBT, making it the version in use today; mathiowetz, Volland, Kashman, and Weber established the BBT's normative test data in 1985.

The degree of flexibility of human fingers is closely related to cognitive function, so that BBT is widely applied to diagnosis, treatment and rehabilitation of diseases such as mild cognitive dysfunction, senile dementia, cerebral apoplexy, cerebral palsy, Parkinson's syndrome and the like. The results of studies performed on stroke patients indicate that the predicted effect of BBT is superior to that of the classical Nine-well cylindrical Test plate (Nine Hole Peg Test), french Arm Test, Grip Strength and STREAM tests. Related studies have also explored the concurrent effectiveness of BBT and found that the BBT Test results are highly relevant to both the Action Research Arm Test and Nine-well cylindrical Test plate (Nine Hole Peg Test) Test results, both before and after treatment.

In clinical diagnosis, doctors evaluate the test results of the BBT by recording videos, observing on site and the like, a great deal of time and energy are consumed in the analysis process, and the analysis results lack objective standards and are low in reliability. In recent years, in order to construct a digital BBT test system, researchers mostly use a depth camera to monitor the test process of a subject, and realize automatic upper limb flexibility assessment through depth data analysis. The system realizes automatic counting of the square blocks in the BBT system through image segmentation, but generally faces the challenges of serious shielding of the test wood blocks and difficult image segmentation, and is difficult to realize accurate data analysis. In addition, the test system based on the depth camera has the problems of high equipment cost, insufficient use convenience and invasion of privacy of a subject, so that the wide use of the test system in clinic, community and family is difficult to realize.

In view of the above, it is apparent that there are many inconveniences and disadvantages in the prior art in practical use, and therefore, there is a need for improvement.

Disclosure of Invention

In view of the above defects, the present invention provides an electronic three-dimensional color Block disorder Test (eBBT) system for an intelligent touch terminal, and provides a simpler, more convenient and more accurate single-side finger flexibility Test method for diagnosis, treatment and rehabilitation of diseases such as mild cognitive dysfunction and senile dementia.

Specifically, the invention discloses an electronic three-dimensional color lump obstacle testing system which is arranged at an intelligent touch terminal and is characterized by comprising the following components:

the information input unit is used for recording the information of the test object;

the testing unit comprises a mirror image testing module and a task testing module and is used for the practice and the test of the testing object on the testing task;

the data analysis unit is used for receiving the test data sent by the task test module and analyzing the test data to obtain a test result;

and the file storage unit is used for receiving and storing the information, the test data and the test result of the test object.

The system for testing the electronic three-dimensional color block obstacle is characterized in that the mirror image test module provides a mirror image test function, and sets and plays a mirror image test video to a test object.

The electronic three-dimensional color block obstacle testing system is characterized in that the task testing module comprises a single-task testing module and/or a double-task testing module which respectively provide a single-task testing function and/or a double-task testing function.

The electronic three-dimensional color block obstacle testing system is characterized in that the task testing module is further provided with:

The three-dimensional color blocks with different colors are used for realizing visual space stimulation;

the barrier units are used for standardizing and training the actions of the test objects;

a plurality of target areas for restrictions on the operation of the test object;

the recording and voice analyzing function is used for recognizing the double-task completion condition of the input and analysis test object;

the left-hand and right-hand selection function is used for selecting the left hand or the right hand to test the test object;

the state indicating area is used for displaying the current residual exercise or test time of the test object and the number of the current moved three-dimensional color blocks;

the multi-posture control test task is used for practicing and testing a test object; and/or

A plurality of cognitive testing tasks for testing the practice and testing of a subject in the dual task test.

The electronic three-dimensional color block obstacle testing system is characterized in that the single-task test executes a posture control test task.

The electronic three-dimensional color block obstacle testing system is characterized in that the double-task test simultaneously executes a posture control testing task and a cognitive testing task.

The system for testing the electronic stereoscopic color block obstacle is characterized in that the left and right hands select functions and are set as follows:

In the right-hand state, the three-dimensional color block needs to be moved to a right target area from the left side of the intelligent touch terminal screen; and in a left-hand state, the three-dimensional color block needs to be moved to a left target area from the right side of the screen of the intelligent touch terminal.

The obstacle testing system for the three-dimensional color block building block box is characterized in that the single-task test data analyzed by the data analysis unit comprises: the path information of the moving three-dimensional color blocks, the number of the correctly moving three-dimensional color blocks with four different colors, continuous correct times, the average time length of the correctly moving three-dimensional color blocks, the maximum time length of the correctly moving three-dimensional color blocks, the minimum time length of the correctly moving three-dimensional color blocks, the number of the wrongly moving three-dimensional color blocks with four different colors, continuous error times, the average time length of the wrongly moving three-dimensional color blocks, the maximum time length of the wrongly moving three-dimensional color blocks and/or the minimum time length of the wrongly moving three-dimensional color blocks.

The system for testing the electronic stereoscopic color block obstacle is characterized in that the multitask test data analyzed by the data analysis unit comprises: and moving the path information and/or the voice information of the three-dimensional color blocks.

The system for testing the electronic stereoscopic color block obstacle is characterized in that the path information comprises a timestamp, a finger contact abscissa, a finger contact ordinate and/or selected stereoscopic color block ID information.

The system for testing the electronic stereoscopic color block obstacle is characterized in that the voice information comprises the consistency and/or accuracy of voice.

In order to realize another purpose of the invention, the invention also provides an upper limb flexibility test device based on the intelligent touch terminal, which comprises the electronic three-dimensional color block disorder test system, and can fully utilize the advantages of the electronic three-dimensional color block disorder test system in the aspects of diagnosis, treatment, rehabilitation and the like of diseases such as mild cognitive dysfunction, senile dementia and the like.

In order to achieve another purpose of the invention, the invention also provides an implementation method of the upper limb flexibility test device based on the intelligent touch terminal, and the implementation method can be used for providing a quick, simple and convenient diagnosis, treatment and rehabilitation method for diseases such as mild cognitive dysfunction and senile dementia by realizing electronic touch screen operation.

In order to achieve the above object, the present invention provides an implementation method of an upper limb flexibility test apparatus based on an intelligent touch terminal, wherein the implementation method comprises:

Setting an information input unit for recording the information of the test object;

setting a test unit, wherein the test unit is used for the practice and test of the test object on a test task and comprises a mirror image test module and a task test module;

a step of setting a data analysis unit, which is used for receiving and analyzing the test data sent by the task test module to obtain a test analysis result;

setting a file storage unit, which is used for receiving and storing the information of the test object, the task test data and the test analysis result;

the system for testing the electronic three-dimensional color block obstacle is characterized in that the mirror image test module provides a mirror image test function, and sets and plays a mirror image test video to a test object.

The electronic three-dimensional color block obstacle testing system is characterized in that the task testing module comprises a single-task testing module and/or a double-task testing module which respectively provide a single-task testing function and/or a double-task testing function.

The electronic three-dimensional color block obstacle testing system is characterized in that the task testing module is further provided with:

the three-dimensional color blocks with different colors are used for realizing visual space stimulation;

The barrier units are used for standardizing and training the actions of the test objects;

a plurality of target areas for restrictions on the operation of the test object;

the recording and voice analyzing function is used for recognizing the double-task completion condition of the input and analysis test object;

the left-hand and right-hand selection function is used for selecting the left hand or the right hand to test the test object;

the state indicating area is used for displaying the current residual exercise or test time of the test object and the number of the current moved three-dimensional color blocks;

the multi-posture control test task is used for practicing and testing a test object; and/or

A plurality of cognitive testing tasks for testing the practice and testing of a subject in the dual task test.

The electronic three-dimensional color block obstacle testing system is characterized in that the single-task test executes a posture control test task.

The electronic three-dimensional color block obstacle testing system is characterized in that the double-task test simultaneously executes a posture control testing task and a cognitive testing task.

The system for testing the electronic stereoscopic color block obstacle is characterized in that the left and right hands select functions and are set as follows:

in the right-hand state, the three-dimensional color block needs to be moved to a right target area from the left side of the screen of the intelligent touch terminal; and in the left-hand state, the three-dimensional color block needs to be moved to a left target area from the right side of the screen of the intelligent touch terminal.

The system for testing the electronic stereoscopic color block obstacle is characterized in that the single task test data analyzed by the data analysis unit comprises: the path information of the moving three-dimensional color blocks, the number of the correctly moving three-dimensional color blocks with four different colors, continuous correct times, the average time length of the correctly moving three-dimensional color blocks, the maximum time length of the correctly moving three-dimensional color blocks, the minimum time length of the correctly moving three-dimensional color blocks, the number of the wrongly moving three-dimensional color blocks with four different colors, continuous error times, the average time length of the wrongly moving three-dimensional color blocks, the maximum time length of the wrongly moving three-dimensional color blocks and/or the minimum time length of the wrongly moving three-dimensional color blocks.

The system for testing the electronic stereoscopic color block obstacle is characterized in that the multitask test data analyzed by the data analysis unit comprises: and moving the path information and/or the voice information of the three-dimensional color blocks.

The electronic three-dimensional color block obstacle testing system is characterized in that the path information comprises a timestamp, a finger contact abscissa, a finger contact ordinate and/or selected three-dimensional color block ID information.

The system for testing the electronic stereoscopic color block obstacle is characterized in that the voice information comprises the continuity and/or accuracy of the voice.

In order to achieve another object of the present invention, the present invention also provides a storage medium for storing a computer program for executing the above method.

In order to make the aforementioned features and effects of the present invention more comprehensible, embodiments accompanied with figures are described in detail below.

Drawings

FIG. 1 is a block diagram of a BBT physical plate

FIG. 2 is a basic block diagram of an electronic BBT testing system

FIG. 3 is a flowchart of the mirror task testing work

FIG. 4 is a BBT and electronic BBT test mapping chart

FIG. 5a is a diagram of the corresponding target area of the electronized BBT test subtest task 1

FIG. 5b is the corresponding target area of the electronized BBT sub-test task 2

FIG. 5c shows the corresponding target area of the electronic BBT sub-test task 3

FIG. 6 is a flow chart of the task testing work of the electronic BBT testing list

FIG. 7a is a flow chart of the work of the electronic BBT test single task test subtask 1

FIG. 7b is a flow chart of the work flow of the electronic BBT test single task test subtask 2

FIG. 7c is the work flow chart of the sub task 3 of the electronic BBT test sheet task test

FIG. 8 is a flow chart of the work flow of the electronic BBT test dual task test

FIG. 9 is the youth interface of Huazhi tablet computer M5

FIG. 10 is a desktop icon of an electronic BBT test system

FIG. 11 shows the starting interface of the electronic BBT test system

FIG. 12 is a basic information entry interface of a user of the electronic BBT test system

FIG. 13 is an electronic BBT test system test cell interface

FIG. 14 is a task interface of an electronic BBT test system

FIG. 15 is a left and right hand operation interface of the electronic BBT testing system

FIG. 16 is a task test interface of the mirror image of the electronic BBT test system

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the following detailed description will be made on the e-Box-and-Block Test system for the electronic stereoscopic color Block obstacle proposed by the present invention with reference to the accompanying drawings. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

In one embodiment of the invention, the invention provides an electronic three-dimensional color Block obstacle Test (e-Box-and-Block Test) system for finger flexibility tests, the overall architecture of the system is shown as figure 2, the system is composed of modules such as a user basic information input module 1, a Test unit 2, a data analysis unit 3, a file system 4 and the like, and the rapid, simple, low-cost, objective and intelligent single-side finger flexibility Test is realized through core functions such as a mirror image task Test 21, a single task Test 221, a double task Test 222 and the like.

The invention aims to provide an electronic three-dimensional color Block obstacle Test (e-Box-and-Block Test) Test system facing an intelligent touch terminal, which is named as eBBT. The eBBT comprises modules such as a user basic information entry 1, a test unit 2, a data analysis unit 3, a file system 4 and the like. The user basic information input module 1 can collect basic information such as user name, gender, age and the like; the data analysis unit 3 provides a function of analyzing single task related test data such as successful movement times 31, movement efficiency 32, movement path analysis and the like and double task related test data such as double task voice 33 and the like; the file system 4 provides functions of storing test basic data and preliminary analysis results and the like; the test unit 2 is the core of the eBBT system, and provides functions of the mirror task test 21, the single task test 221, the double task test 222, and the like.

The mirror task test 21 is designed according to the mirror neuron theory. The mirror neuron refers to a feedback system in which a user activates a cortical neuron that itself performs an action by observing the action of another person, that is, an action observation-execution matching system. During the testing process, the mirror image task test induces the activation of neurons related to the movement of the brain cortex and the hands of the user by guiding the user to watch the mirror image test video recorded by a doctor. The workflow of the mirror image task test is shown in fig. 3, and mainly includes:

S11, inputting basic information such as user name, gender, age and the like;

s12, clicking to enter a mirror image test unit;

s13, guiding the user to watch the mirror image test video, introducing the mirror image test task for the user, and guiding the user

Imagine a corresponding action;

s14, finishing the primary mirror image test task;

and ending the mirror image test task, closing the mirror image test unit and returning to the BBT test task.

The eBBT system is designed according to the physical version BBT test, and for the building blocks, baffles, boxes and other elements in the physical version BBT test, the eBBT system is correspondingly implemented, as shown in fig. 4. Building blocks a in four colors are designed in a real object version BBT, and three-dimensional color blocks A in four colors of red, green, blue and yellow are correspondingly designed in an eBBT system so as to realize effective visual space stimulation; the baffle B in the physical BBT is used for standardizing the upper limb movement of the user to obtain large-range exercise training, and the eBBT system is correspondingly provided with the blocking unit B to realize the standardization and training of the user movement; box C in the real object version BBT is used for holding building blocks after moving and standardizes the building block delivery area, and target area C has also been correspondingly designed in the eBBT system to the restriction of realization to user operation.

According to different target areas, a single task of the eBBT system generally consists of three sub-test tasks, namely task 1, task 2 and task 3. Each sub-test task target area is as shown in fig. 5, task 1 (fig. 5a) only requires the user to move the solid color block a to the corresponding target area C; task 2 (FIG. 5b) requires the user to move the solid patch A of a different color to the corresponding color target area C1, C2, C3, C4, e.g., the red solid patch moves to the red target area and the blue solid patch moves to the blue target area; task 3 (fig. 5C) requires the user to sequentially move the stereoscopic color blocks to the corresponding areas 1, 2, 3, 4, … …, and 12 in the target area C, the nth target area is covered with the stereoscopic color blocks, and then the stereoscopic color blocks can be placed in the (N + 1) th target area, and if the stereoscopic color blocks are all placed in the 12 target areas, the above operations are repeated from the 1 st target area.

The work flow diagram of the single task test of the eBBT system is shown in fig. 6, and mainly includes:

s21, selecting which single test task to perform, such as task 1, task 2 and task 3;

s22, selecting to use the left hand or the right hand to carry out single task testing;

s23, single task test instruction;

s24, performing 15S single task test practice;

S25, performing 1min single task test;

s26, ending the single task test;

s27, displaying a single task test result;

and ending the single task test.

The work flow chart of each subtask in the single task test of the eBBT system is shown in fig. 7, and mainly includes:

starting an eBBT single task test;

(1) if eBBT test task 1 is selected (see FIG. 7 a);

s31, selecting to use right hand or left hand to carry out task 1 test according to the test requirement;

s3211, selecting a left hand for testing;

s3212, providing a left-handed test description of the task 1;

s3213, carrying out 15S left-handed test practice;

s3214, performing a left-handed test for 1 min;

s3215, ending the left-hand test;

s3221, selecting a right hand to test;

s3222, a right-hand testing description of the task 1 is given;

s3223, carrying out 15S right-hand test practice;

s3224, performing a right-hand test for 1 min;

s3225, the right-hand test is finished

S33, displaying the test result of the eBBT task 1 right hand or left hand;

after the left-hand (right-hand) test of the task 1 is finished, the left-hand (right-hand) test of the task 1 is repeatedly carried out or the right-hand (left-hand) test of the task 1 is continuously carried out according to requirements;

(2) if eBBT test task 2 is selected (FIG. 7 b);

s41, selecting to use right hand or left hand to carry out task 2 test according to the test requirement;

S4211, starting a left-hand test;

s4212, giving a left-handed test description of task 2;

s4213, performing 15S left-hand test practice;

s4214, performing a 1min left-handed test;

s4215, finishing the left-hand test;

s4221, starting a right-hand test;

s4222, giving a task 2 right-hand test description;

s4223, performing 15S of right-hand test practice;

s4224, performing a right-hand test for 1 min;

s4225, ending the right-hand test;

s43, displaying the right-hand or left-hand test result of the eBBT task 2;

after the left-hand (right-hand) test of the task 2 is finished, the left-hand (right-hand) test of the task 2 is repeatedly carried out or the right-hand (left-hand) test of the task 2 is continuously carried out according to requirements;

(3) if eBBT test task 3 is selected (see FIG. 7c)

S51, selecting to use right hand or left hand to carry out task 3 test according to the test requirement;

s5211, starting a left-hand test;

s5212, a left-hand test description of the task 3 is given;

s5213, carrying out 15S left-hand test practice;

s5214, performing a left-handed test for 1 min;

s5215, finishing the left-hand test;

s5221, starting a right-hand test;

s5222, giving a task 3 right-hand test description;

s5223, performing 15S right-hand test practice;

s5224, performing a right-hand test for 1 min;

s5225, the right-hand test is finished;

s53, displaying the right-hand or left-hand test result of the eBBT task 3;

After the left-hand (right-hand) test of the task 3 is finished, the left-hand (right-hand) test of the task 3 is repeatedly carried out or the right-hand (left-hand) test of the task 3 is continuously carried out according to the requirement;

the eBBT single task test is finished.

The multitask test task is designed according to a multitask research paradigm, and requires a user to simultaneously execute a posture control task and a cognitive task. The double-task test focuses on the problem of mutual influence of cognition and neuromuscular behavior control, and can effectively simulate a multi-task scene in real life. Three sets of two-task tests were generally designed in the eBBT system, 100 reciprocal, animal name and 100 minus 7, respectively. The reciprocal of 100 requires that the user performs left-right single-task testing, and at the same time, reciprocal Arabic numerals are started from 100, such as 100, 99, 98 and … …; animal naming dual tasks require a user to speak as many animal names as possible while completing a left-hand and right-hand single task test, such as monkey, puppy, kitten, rabbit, … …; the 100 minus 7 double task requires the user to speak the next digit after minus 7 in turn from 100, such as 100, 100-7 ═ 93, 93-7 ═ 86, 86-7 ═ 79, … …, while completing the left and right hand single task test. In the double-task testing process, the eBBT system provides a voice analysis function of the recorder and identifies the double-task completion condition of the user. Fig. 8 shows a flow chart of the dual task test, which mainly includes:

S61, selecting which double task test is to be carried out, such as no double task, 100 reciprocal double task, animal naming double task and 100 minus 7 double task;

s62, selecting which single task test to perform, such as task 1, task 2 and task 3;

s63, selecting to use the left hand or the right hand to carry out double-task testing;

s64, dual-task test description;

s65, performing 15S double-task test practice;

s66, performing 1min double-task test;

s67, ending the double-task test;

s68, displaying a double-task test result;

the dual task test is ended.

In another embodiment of the present invention, the present invention further includes an intelligent terminal for testing upper limb flexibility, where the terminal may be a computer system application terminal, or an intelligent terminal disposed in a server, or an intelligent testing device implemented by interaction between a computer system and a server.

In another embodiment of the invention, an implementation method of an electronic three-dimensional color Block obstacle testing (e-Box-and-Block Test) system based on an intelligent touch terminal is disclosed.

1. Apparatus and device

The present invention uses, but is not limited to, Android development language and Huacheng tablet computer M5 adolescent edition, as shown in FIG. 9. The M5 youth tablet computer screen size was 10.1 with a screen resolution of 1920 × 1200. The eBBT desktop icon is shown in fig. 10 and the start interface is shown in fig. 11.

2. User basic information entry

The user base entry module asks the user to enter his name, age and gender information as shown in fig. 12.

3. Test unit

The test unit is the core of the eBBT system, and provides functions of mirror task testing, single task testing, double task testing, and the like, and an interface is shown in fig. 13. The respective functions are described as follows:

(1) test exercise function selection

Two pull-down keys of 'exercise' and 'test' are provided, and in an exercise state, a user can practice skilled eBBT operation for 15s without providing data storage and analysis functions; in the test state, the user initiates a 1 minute official test procedure that provides data storage and analysis functions.

(2) Task selection

Three pull-down keys of task 1, task 2 and task 3 are provided, and target area rules are set differently in the three task states. Task 1 (fig. 14(a)) only requires moving blocks across the partition to the target area; task 2 (fig. 14(b)) requires not only moving the blocks across the partition to the target area, but also placing the blocks in the corresponding color areas, e.g., red blocks in the red target area, blue blocks in the blue target area; task 2 (fig. 14(c)) requires that blocks be placed in sequence in target areas 1, 2, 3, … …, 12 according to the sequence numbers, and only after the nth target area has placed blocks, the (N + 1) th target area can place blocks.

(3) Dual task selection

Four pull-down keys of "none", "100 reciprocal", "animal name", "100 minus 7" are provided. In the state without double tasks, the user only needs to complete single task test; under 100 reciprocal double tasks, the user needs to start reciprocal Arabic numbers such as 100, 99, 98, … …, 60 and … … from 100 while completing the single task test, and the process provides a recording function for analyzing the double task completion condition of the user; under the animal naming dual-task condition, a user needs to speak the names of animals such as monkeys, puppies, kittens, piglets and … … as much as possible while completing a single-task test, and the process provides a recording function and is used for analyzing the dual-task completion condition of the user; under the double tasks of subtracting 7 from 100, the user needs to sequentially speak numbers after subtracting 7 from 100, such as 100, 100-7 being 93, 93-7 being 86, … …, while completing the single task test, and the process provides a recording function for analyzing the double task completion of the user.

(4) Left and right hand selection

Two pull-down keys of 'right hand' and 'left hand' are provided. In the right-hand (fig. 15(a)) state, the user is asked to move the block from the left to the right target area of the screen; in the left-hand (fig. 15(b)) state, the user is asked to move the block from the right to the left target area of the screen.

(5) Start button

After clicking, the eBBT system begins to enter a practice or test program.

(6) Status indication column

Indicating the current exercise or testing time remaining for the user, and the number of blocks that have been moved.

(7) Mirror image test unit

And the video for the physical BBT test of the doctor is played to guide the user to imagine corresponding actions.

4. Data analysis unit

And the data analysis unit analyzes the single-task test result and the double-task test result of the user according to the user test data. The single task test result analyzes the number of correctly moved blocks, the number of correctly moved red blocks, the number of correctly moved blue blocks, the number of correctly moved green blocks, the number of correctly moved yellow blocks, the number of consecutive correct times, the average time length of correctly moved blocks, the maximum time length of correctly moved blocks, the minimum time length of correctly moved blocks, the number of incorrectly moved red blocks, the number of incorrectly moved blue blocks, the number of incorrectly moved green blocks, the number of incorrectly moved yellow blocks, the number of consecutive error times, the average time length of incorrectly moved blocks, the maximum time length of incorrectly moved blocks, and the minimum time length of incorrectly moved blocks according to the path information of the user for moving blocks. And analyzing the test completion condition according to the path information of the user moving the building block and the voice information by the double-task test result, wherein the path information is the same as the path information in the single-task test, and the voice information analyzes the consistency and the accuracy of the voice information.

5. File system

The file system provides a path information storage function and a voice information storage function in the process of storing the task completed by the user, and the path information completely reproduces the path information tested by the user by recording a timestamp, a finger contact abscissa, a finger contact ordinate and the ID information of the selected building block, so as to provide data support for subsequent analysis; the voice information provides data support for subsequent analysis by recording the voice information in the user double-task completion.

In another embodiment of the present invention, a storage medium for storing a computer processing program for executing the above-described test method is further included.

In a particular embodiment of the invention, the computer program concerned comprises computer program code means adapted to perform all the steps of the method according to the invention when the computer program is run on a computer. Preferably, the computer program is embodied on a computer readable medium.

The invention has the beneficial effects that: by designing an electronic touch-based three-dimensional color Block disorder Test (e-Box-and-Block Test) system, a simpler, faster, lower-cost and objective single-side finger flexibility Test device and method are provided for diagnosis, treatment and rehabilitation of diseases such as mild cognitive dysfunction, senile dementia, cerebral apoplexy, cerebral palsy, Parkinson's syndrome and the like.

The present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof, and it should be understood that various changes and modifications can be effected therein by one skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (12)

1. An electronic three-dimensional color block obstacle testing system, which is characterized by comprising:

the information input unit is used for recording the information of the test object;

the test unit comprises a mirror image test module and a task test module and is used for the practice and the test of the test object on the test task;

the data analysis unit is used for receiving and analyzing the task test data to obtain a test result;

the file storage unit is used for receiving and storing the information, the test data and the test result of the test object and outputting the test result;

the task testing module is also provided with:

the touch display module is used for displaying various three-dimensional color blocks with different colors and realizing visual space stimulation; displaying a plurality of barrier units for standardizing and training the actions of the test object; displaying a plurality of target areas for restriction of the test object operation; the display state indicating area is used for displaying the current residual exercise or test time of the test object and the number of the current moved three-dimensional color blocks;

The recording and voice analyzing function is used for identifying the double-task completion condition of the input and analysis test object;

the left-hand and right-hand selection function is used for selecting the left hand or the right hand to test the test object;

the multi-posture control test task is used for practicing and testing a test object in the single-task test;

a plurality of cognitive test tasks for the practice and testing of a test subject in the dual task test;

the single task test data analyzed by the data analysis unit includes: the path information of the moving three-dimensional color blocks, the number of the correctly moving three-dimensional color blocks with four different colors, continuous correct times, the average time length of the correctly moving three-dimensional color blocks, the maximum time length of the correctly moving three-dimensional color blocks, the minimum time length of the correctly moving three-dimensional color blocks, the number of the wrongly moving three-dimensional color blocks with four different colors, continuous error times, the average time length of the wrongly moving three-dimensional color blocks, the maximum time length of the wrongly moving three-dimensional color blocks and the minimum time length of the wrongly moving three-dimensional color blocks.

2. The system for testing solid color block obstacles electronically as claimed in claim 1, wherein said mirror image test module provides mirror image test function, sets and plays mirror image test video to the test object.

3. The system according to claim 1, wherein the task test module comprises a single task test module and a double task test module, respectively providing a single task test function and a double task test function.

4. The system according to claim 3, wherein the single task test performs a gesture control test task.

5. The system for testing stereoscopic color block disorders electronically of claim 3, wherein the dual task test performs a gesture control test task and a cognitive test task simultaneously.

6. The system for testing stereoscopic color block disorder in electronized claim 1, wherein the left and right hand selection function is set to:

in the right-hand state, the three-dimensional color block needs to be moved to a right target area from the left side of the screen of the intelligent touch terminal; and in the left-hand state, the three-dimensional color block needs to be moved to a left target area from the right side of the screen of the intelligent touch terminal.

7. The system for testing stereoscopic color block obstacle electronically as recited in claim 1, wherein the multitask test data analyzed by the data analyzing unit comprises: and moving the path information and the voice information of the three-dimensional color blocks.

8. The electrified stereoscopic color lump obstacle testing system of claim 7, wherein the path information comprises a timestamp, finger contact abscissas, finger contact ordinates, and/or selected stereoscopic color lump ID information.

9. The system of claim 8, wherein the speech information comprises a continuity and/or an accuracy of speech.

10. An intelligent touch terminal-based testing device, comprising the electronic stereoscopic color block obstacle testing system of any one of claims 1 to 9.

11. An implementation method for the intelligent touch terminal based test device of claim 10.

12. A storage medium storing a computer program for executing the method of claim 11.

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