CN117298407A - Interactive control method for brain function rehabilitation training device - Google Patents

Abstract

The application provides an interactive control method for a brain function rehabilitation training device, which comprises the following steps that under the condition that a training object is ready to execute a brain function training program: receiving a first interactive operation of setting a target near-infrared head cap to be used by a user through a near-infrared head cap setting interface, wherein the target near-infrared head cap corresponds to at least one probe arrangement; receiving a second interactive operation of a user aiming at a target near infrared headgear indication to select a target acquisition channel; responding to the first interactive operation and the second interactive operation, and presenting an acquisition channel setting interface corresponding to the near infrared headgear of the target; and receiving a third interactive operation of selecting a target acquisition channel from target acquisition channel setting items corresponding to brain function training items by a user, wherein the target acquisition channel is selected from at least partial acquisition channels in target probe arrangement, and providing feedback content for a training object based on near infrared data of the target acquisition channel when the training object executes the brain function training items.

Description

Interactive control method for brain function rehabilitation training device

Technical Field

The application relates to the technical field of brain function rehabilitation training, in particular to an interactive control method of a brain function rehabilitation training device.

Background

The brain function training technology takes a nerve plasticity mechanism as a theoretical support, and through detecting nerve activity signals in real time, the nerve activity signals are fed back to a training object in a visual, auditory or other sensory form through on-line processing, the training object is required to perform autonomous adjustment according to the feedback signals, so that the adjustment of specific nerve activities (brain activation, brain connection and the like) is realized, and finally, the improvement/improvement of individual cognition/behavior performance is realized.

Through half a century development, a great deal of basic research and clinical experiments are carried out in the field of brain function training, and great deal of results are obtained in the aspects of improving cognitive ability and task performance, treating attention deficit and hyperactivity syndrome (ADHD), autism, cognitive aging, limb movement disorder and the like. Near infrared imaging technology is one of the common means of performing brain activity measurements.

In the prior art, in order to realize effective linkage between the near infrared data acquisition system and the cognitive function rehabilitation training device, before starting rehabilitation training, a user is required to select the type of head cap adopted when the near infrared data acquisition system acquires data on the cognitive function rehabilitation training device, however, in the prior cognitive function rehabilitation training device, the probe arrangement corresponding to each head cap is fixed, the detection brain regions aiming at various training types are also fixed, however, in the training task, the user may be different in the brain region of interest of a training object, the detection brain regions aiming at each training type and the probe arrangement in the prior art are both fixed, the feedback result is also aiming at the fixed brain region, the requirements of the user on detecting and feeding back the activation conditions to different brain regions of interest are difficult to meet, if the head cap arranged based on the brain region of interest is manufactured, then the rehabilitation training task is required to be consumed, and the user requirements are difficult to be met one by one.

Disclosure of Invention

Aiming at the technical problems in the prior art, the application provides an interactive control method for a brain function rehabilitation training device, which can select a target acquisition channel of a region of interest in a simple and convenient mode, and only uses near infrared detection data of the brain region of interest obtained by the target acquisition channel to feed back the brain activation condition of the brain region of interest in the training process to a user, thereby meeting the requirement that the user hopes to know the brain activation condition of the brain region of interest, having low cost and flexible mode, and having the degree of freedom of selecting the brain region of interest by the user.

According to a first aspect of the present disclosure, an interactive control method for a brain function rehabilitation training device is provided. The brain function rehabilitation training device provides brain function training items for a training object and provides feedback content for the training object based on near infrared data of the training object. The interactive control method includes, in a case where the training object is ready to perform a brain function training program: the method comprises the steps of receiving first interactive operation of setting a target near-infrared head cap to be used by a user through a near-infrared head cap setting interface, wherein the target near-infrared head cap corresponds to at least one probe arrangement. And receiving a second interactive operation of a user aiming at the target near infrared head cap indication to select a target acquisition channel. And responding to the first interactive operation and the second interactive operation, and presenting an acquisition channel setting interface corresponding to the target near infrared headgear. The acquisition channel setting interface at least comprises target probe arrangement, brain function training items and target acquisition channel setting items. And receiving a third interactive operation of selecting a target acquisition channel from the target acquisition channel setting items corresponding to the brain function training items by the user. And the target acquisition channels are selected from at least part of acquisition channels in the target probe arrangement, and when a training object executes the brain function training program, feedback content is provided for the training object based on near infrared data of the target acquisition channels.

According to a second aspect of the present application, there is provided a brain function rehabilitation training device comprising at least a processor. The processor is configured to perform an interactive control method for a brain function rehabilitation training device according to various embodiments of the present application.

According to a third aspect of the present application, there is provided a storage medium having a computer program stored thereon. The computer program, when executed by a processor, implements an interactive control method for a brain function rehabilitation training device according to various embodiments of the present application.

Compared with the prior art, the beneficial effects of the embodiment of the application are that:

in the embodiment of the application, before a training object performs a brain function training program, a user selects a target near-infrared headgear by setting a brain region of interest in a brain function rehabilitation training device, and then selects a near-infrared data acquisition channel of a target probe arrangement of the target near-infrared headgear, the selected acquisition channel is processed into a target acquisition channel of the brain region of interest, and when a subsequent training object performs the brain function training program, feedback content is provided for the training object based on the near-infrared data of the target acquisition channel, for example, the feedback main body is fed back to the user to change related to the activation condition of the brain region of interest and the activation condition of the brain region of interest before and after training, thereby meeting the requirement that the user hopes to know the brain activation condition of the brain region of interest, so that the user knows the brain function condition of the training object and adjusts the training or treatment strategy in time. The method for designing the brain region of interest by the user is simple, convenient and low in cost, the target acquisition channels can be freely selected according to the requirements on the brain region of interest, the flexibility is high, the user does not need to customize the head caps arranged by different probes according to the requirements, for example, the head caps arranged by one type of probe can be used for selecting the target acquisition channels which are arbitrarily combined as the brain region of interest, in the training process, the brain function rehabilitation training device calculates the training result of the brain region of interest by only using the near infrared data of the target acquisition channels, and compared with the condition that the acquisition channels cannot be selected, the calculation scale is reduced in a mode which is adaptive to the number of the acquisition channels, so that the training result feedback efficiency of the brain function rehabilitation training device can be improved.

Drawings

In the drawings, which are not necessarily drawn to scale, like numerals may describe similar components in different views. The same reference numerals with letter suffixes or different letter suffixes may represent different instances of similar components. The accompanying drawings illustrate various embodiments by way of example in general and not by way of limitation, and together with the description and claims serve to explain the disclosed embodiments. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts. Such embodiments are illustrative and not intended to be exhaustive or exclusive of the present apparatus or method.

FIG. 1 illustrates a schematic view of a usage scenario of an interactive control method for a brain function rehabilitation training device according to an embodiment of the present application;

FIG. 2 illustrates a first flowchart of an interactive control method for a brain function rehabilitation training device according to an embodiment of the present application;

FIG. 3 illustrates a near infrared headgear setup interface for an interactive control method of a brain function rehabilitation training device according to an embodiment of the present application;

FIG. 4 illustrates an acquisition channel setup interface for an interactive control method of a brain function rehabilitation training device according to embodiments of the present application;

FIG. 5 shows a second flowchart of an interactive control method for a brain function rehabilitation training device according to an embodiment of the present application;

FIG. 6 illustrates a third flowchart of an interactive control method for a brain function rehabilitation training device according to an embodiment of the present application;

FIG. 7 illustrates a target training item selection interface for an interactive control method of a brain function rehabilitation training device according to embodiments of the present application;

FIG. 8 illustrates a training task creation interface for an interactive control method of a brain function rehabilitation training device according to embodiments of the present application;

FIG. 9 illustrates a fourth flowchart of an interactive control method for a brain function rehabilitation training device according to an embodiment of the present application;

FIG. 10 illustrates an editing interface schematic of a training report for an interactive control method of a brain function rehabilitation training device according to embodiments of the present application; and

fig. 11 shows a fifth flowchart of an interactive control method for a brain function rehabilitation training device according to an embodiment of the present application.

The reference numerals in the drawings denote components:

100-brain function rehabilitation training device; 101-a near infrared data acquisition module; 102-a display module;

3-near infrared headgear setup interface; 31-headgear selection frame; 32-headgear modification options; 33-headgear new options; 34-headgear delete option;

4-setting an interface of the acquisition channel; 41-a headgear information input field; 42-target probe arrangement; 43-brain function training program; 44-target acquisition channel settings; 45-target acquisition channel picture import item;

7-a target training item selection interface; 71-target brain function training program; 72-create task options;

8-training task creation interface; 81-a probe layout display area; 82-target acquisition channel labeling.

Detailed Description

In order to better understand the technical solutions of the present disclosure, the following detailed description of the present disclosure is provided with reference to the accompanying drawings and the specific embodiments. Embodiments of the present disclosure will be described in further detail below with reference to the drawings and specific embodiments, but not by way of limitation of the present disclosure. The order in which the steps are described herein by way of example should not be construed as limiting if there is no necessity for a relationship between each other, and it should be understood by those skilled in the art that the steps may be sequentially modified without disrupting the logic of each other so that the overall process is not realized.

In some embodiments of the present application, an interactive control method for a brain function rehabilitation training device is provided. The brain function rehabilitation training device provides brain function training items for a training object and provides feedback content for the training object based on near infrared data of the training object.

Specifically, as shown in fig. 1, fig. 1 is a schematic view of a usage scenario of an interactive control method for a brain function rehabilitation training device according to an embodiment of the present application. The user can select a training item to be performed among the brain function training items provided in the brain function rehabilitation training device 100. The brain function rehabilitation training device 100 comprises a near infrared data acquisition module 101 and a display module 102. When the training subject performs the selected training program, the brain function rehabilitation training device 100 can determine feedback content based on the near infrared data acquired by the near infrared data acquisition module 101, and feedback the feedback content to the training subject in a preset form on the display interface of the display module 102.

In some embodiments, the brain function training program may include a motor imagery training program for treating limb movement disorders, an attention training program for treating attention deficit disorders, a memory training program for treating cognitive disorders, and the like. During the training process, a feedback main body is presented on the display interface of the brain function rehabilitation training device 100, and the feedback main body changes with the brain activation condition of the training subject for executing the brain function training program, wherein the brain activation condition is determined by near infrared data acquired by the training subject when executing the brain function training program. For example, in an attention training program, the training task is to concentrate on imagining the kite fly high, during the training process, near infrared data of the training object is collected, and the lift of the kite is controlled by the collected near infrared data to represent the brain activation condition of the training object, for example, if the kite is lifted, the brain activation condition is better, and if the kite is lowered, the brain activation condition is worse.

In particular, the near infrared data acquisition module 101 may be understood as being configured to acquire near infrared data based on which one or more of the following physiological parameters characterizing the functional state of the brain may be derived: oxyhemoglobin concentration value (HbO), deoxyhemoglobin concentration value (HbR), total hemoglobin concentration value (HbT).

As shown in fig. 2, the flow of the interactive control method for the brain function rehabilitation training device 100 includes steps S1 to S4. In the case where the training subject is ready to perform a brain function training program, the above-described interactive control method performs steps S1 to S4.

In step S1, a first interactive operation is received in which a user sets a target near-infrared headgear to be used via the near-infrared headgear setting interface 3, the target near-infrared headgear corresponding to at least one probe arrangement.

Specifically, the above-described user may be understood as an operator, such as a doctor, a rehabilitation therapist, or the like, who operates the brain function rehabilitation training device 100.

Illustratively, the display interface shown in fig. 3 is specifically a near infrared headgear setup interface 3. As shown in fig. 3, options for various types of near infrared headgear for achieving brain function rehabilitation training may be presented on the near infrared headgear setting interface 3. After determining the near infrared headgear for performing the brain function rehabilitation training, the user may set the target near infrared headgear to be used by checking the headgear selection frame 31 of the corresponding near infrared headgear on the near infrared headgear setting interface 3, for example, checking the selection frame in front of the corresponding "headgear name" item in fig. 3, so as to achieve the association between the brain function training item and the near infrared headgear actually adopted by the near infrared data acquisition module 101, so that the feedback content presented by the training subject when performing the brain function training item is determined based on the selected target near infrared headgear, and the brain region of interest is set by the user to be selected based on the probe arrangement corresponding to the selected target near infrared headgear.

The above-described target near infrared headgear to be used is set in a sorted manner as just one example, and is not limited thereto. For example, the manner of setting the target near-infrared headgear may be such that an input field for inputting the name of the target near-infrared headgear is presented on the near-infrared headgear setting interface 3, and after determining a headgear for performing brain function rehabilitation training, the user may set the target near-infrared headgear to be used by inputting the determined name of the headgear in the input field. Alternatively, a plurality of types of near infrared headgear for realizing brain function rehabilitation training may be presented on the near infrared headgear setting interface 3 in a drop-down option, and after determining a headgear for performing brain function rehabilitation training, the user may set a target near infrared headgear to be used by selecting the name of the determined headgear in the drop-down option. In addition, the above setting of the target near-infrared headgear includes determining the target near-infrared headgear by means of selection or input, and performing operations such as modification or deletion on the determined target near-infrared headgear.

In step S2, a second interactive operation is received indicating to the user for the target near infrared headgear that a target acquisition channel is to be selected.

Illustratively, as shown in FIG. 3, a headgear modification option 32 for each type of near infrared headgear may be presented on the near infrared headgear setup interface 3. The user may modify the custom added near infrared headgear but not the near infrared headgear that the system is self-contained. In the case that the user only needs to obtain the feedback content related to the brain region of interest in the brain function training program, the user can instruct to perform the selection of the target acquisition channel for the target near-infrared headgear by selecting the headgear modification option 32 of the target near-infrared headgear on the near-infrared headgear setting interface 3, for example, clicking the "modification" button behind the corresponding headgear name entry in fig. 3, so as to select a part of the acquisition channels corresponding to the brain region of interest from all the acquisition channels of the target near-infrared headgear to participate in the brain activation feedback of the brain function training program, so that the feedback content provided by the brain function training program subsequently is related to only the brain region of interest and does not provide the feedback content related to the brain region other than the brain region of interest, and thus the user can directly and accurately obtain the brain activation of the brain region of interest.

In step S3, in response to the first interaction operation and the second interaction operation, the acquisition channel setting interface 4 corresponding to the target near infrared headgear is presented. The acquisition channel setting interface 4 at least comprises a target probe arrangement 42, a brain function training item 43 and a target acquisition channel setting item 44.

Illustratively, the "add-on headgear SD" interface shown in fig. 4 is specifically the acquisition channel setup interface 4. As shown in fig. 4, a target probe arrangement 42 and brain function training items 43 corresponding to the target near infrared headgear may be presented on the acquisition channel setup interface 4, and a corresponding target acquisition channel setup item 44 is presented for each brain function training item, respectively. The target probe arrangement 42 may be a number and a name of the target probe arrangement, or may be a picture of the target probe arrangement, and may be presented in a form capable of distinguishing the probe arrangement, where different target probe arrangements 42 include different multiple acquisition channel arrangements. Wherein, each brain function training item 43 may have a corresponding target acquisition channel setting item 44, so that the user may set the target acquisition channel for each brain function training item 43 individually. The content presented on the acquisition channel setting interface 4 is based on the information provided by the target near infrared headgear, and the user can further confirm the training information of the subsequent brain function training program or refine the training content through the presented brain function training program or setting item. Specifically, the user can confirm the arrangement of the target probe currently used by the target near-infrared headgear and the executable brain function training items at the acquisition channel setting interface 4, and can set the target acquisition channel used in each brain function training item through the target acquisition channel setting item 44 of the brain function training item, so as to obtain feedback of brain activation conditions of the brain region of interest corresponding to the target acquisition channel later.

In step S4, a third interactive operation is received in which the user selects a target acquisition channel in the target acquisition channel setting item 44 corresponding to the brain function training item. Wherein the target acquisition channel corresponds to a brain region of interest and is selected from at least part of the acquisition channels in the target probe arrangement. The brain function rehabilitation training device 100 provides feedback contents to the training subject based on near infrared data of the target acquisition channel while the training subject performs the brain function training program.

Illustratively, on the acquisition channel setting interface 4, the target acquisition channel setting item 44 may be presented as an input field for inputting information of an acquisition channel, such as an input field below "acquisition channel number" in fig. 4. The information of the acquisition channels (which may also be referred to as identification information) includes the name, number, etc. of the acquisition channels. The user can select the target acquisition channel by inputting the information of the acquisition channel corresponding to the brain region of interest in the input field, so as to select the acquisition channel actually used for calculating the near infrared data of the brain activation condition feedback of the brain region of interest, thereby enabling the brain function rehabilitation training device 100 to provide the brain activation condition feedback of the brain region of interest to the training object only based on the near infrared data of the target acquisition channel when the training object executes the brain function training project, without using the near infrared data of the acquisition channels other than the target acquisition channel, and the user can directly acquire the brain activation condition of the brain region of interest.

In the interactive control method for the brain function rehabilitation training device 100, before the training object executes the brain function training program, the user sets the brain region of interest in the brain function rehabilitation training device 100, selects the acquisition channel for acquiring near infrared data arranged by the target probe after selecting the target near infrared headgear, the selected acquisition channel is processed into the target acquisition channel of the brain region of interest, and when the subsequent training object executes the brain function training program, feedback content is provided for the training object based on the near infrared data of the target acquisition channel, for example, the change of the main body related to the activation condition of the brain region of interest and the change of the activation condition of the brain region of interest before and after training are fed back to the user, so that the requirement that the user hopes to know the brain activation condition of the brain region of interest is met, and the user can know the brain function condition of the training object and adjust the training or treatment strategy in time. The above-mentioned mode of user design brain district of interest easy operation, convenient and with low costs, can freely select the target acquisition channel according to the demand to the brain district of interest, and the flexibility is strong, need not the user again to customize the headgear that different probes were arranged according to the demand, for example can utilize the headgear that a kind of probe was arranged to select the target acquisition channel of arbitrary combination as the brain district of interest, and in the training process, brain function rehabilitation training device 100 calculates the training result of the brain district of interest through the near infrared data that only uses the target acquisition channel, compare with the condition that can't select the acquisition channel, reduce the calculation scale with the mode that suits with the acquisition channel quantity, thereby can improve the training result feedback efficiency of brain function rehabilitation training device 100.

In some embodiments, as shown in fig. 5, the interactive control method further includes steps S201 to S202. The interactive control method performs steps S201 to S202 before receiving the third interactive operation.

In step S201, a fourth interaction operation is received in which the user determines the target probe arrangement via the acquisition channel setting interface 4.

Specifically, the target probe arrangement is selected from at least one probe arrangement corresponding to the target near-infrared head cap, one near-infrared head cap can correspond to one or more probe arrangements, and the arrangement modes of the acquisition channels corresponding to different probe arrangements are different.

As shown in fig. 4, in the case where the target near infrared headgear has a plurality of probe arrangements, the target probe arrangement 42 on the acquisition channel setting interface 4 assumes an editable state, for example, becomes the editable state shown by the target probe arrangement 42 under the "SD name" in fig. 4. The probe arrangement information of each near infrared head cap is the corresponding probe arrangement. Each near infrared headgear and its probe arrangement information are pre-stored in a memory of the near infrared data collection module 101 in a corresponding manner. When receiving the fourth interactive operation, the brain function rehabilitation training device 100 retrieves probe arrangement information of the target near-infrared headgear from the near-infrared data acquisition module 101 to complete determination of the target probe arrangement, and associates the target probe arrangement with a brain function training item to be executed subsequently.

Illustratively, on the acquisition channel setting interface 4, the target probe arrangement 42 may be determined by way of an input field inputting target probe arrangement information. After determining the probe arrangement for performing brain function rehabilitation training, the user can set the target probe arrangement to be used by inputting the target probe arrangement information in the input field, for example, input the "M number full head cap" in the input field of the target probe arrangement information under the "SD name" in fig. 4. The brain function rehabilitation training device 100 retrieves the probe arrangement information corresponding to the target near infrared headgear, namely the M-number full headgear, from the near infrared data acquisition module 101, and sets the probe arrangement matched with the target probe arrangement information input by the user as the target probe arrangement. In this way, the brain function training items are associated with the probe arrangement actually adopted by the brain function rehabilitation training device 100, and the brain function training items corresponding to the target probe arrangement are enabled to perform the third interactive operation. The target probe arrangement information can be the name of the target probe arrangement or the code of the target probe arrangement. When the probe arrangement information retrieved from the near infrared data acquisition module 101 matches with the target probe arrangement information, the probe arrangement corresponding to the probe arrangement information is set as the target probe arrangement.

The above-described determination of the target probe arrangement to be used by way of input information is merely an example, and is not limited thereto. For example, the manner of determining the target probe arrangement may also be that a plurality of probe arrangements corresponding to the target near infrared headgear are presented on the acquisition channel setting interface 4 in a drop-down option manner, which are retrieved from the near infrared data acquisition module 101. After determining the probe arrangement for performing brain function rehabilitation training, the user can set the target probe arrangement to be used by selecting the determined probe arrangement in the drop-down option.

In step S202, in response to the fourth interactive operation, a brain function training program adapted to the target probe arrangement is presented on the acquisition channel setting interface 4.

Illustratively, only brain function training items corresponding to the target probe arrangement are presented on the acquisition channel setting interface 4, and brain function training items not related to the target probe arrangement are not presented. For example, in the case where the selected target probe arrangement is applicable to only brain function training items of left motor imagery and right motor imagery, then only the two brain function training items described above are presented at the acquisition channel setting interface 4, and no other training items are presented.

In some embodiments, in response to the fourth interaction, in step S202, only brain function training items that are compatible with the target probe arrangement among the brain function training items presented on the acquisition channel setting interface 4 may be selected, and the corresponding target acquisition channel setting item 44 may be edited, while brain function training items that are not related to the target probe arrangement are in a state that cannot be selected.

For example, as shown in fig. 4, brain function training items corresponding to the target near infrared headgear may be presented on the acquisition channel setting interface 4, brain function training items 43 corresponding to the target probe arrangement may be presented in a checkable manner, and corresponding target acquisition channel setting items 44 may be presented in an editable manner, for example, selection boxes in front of items of "left motor imagery", "attention training" and "memory training" may be presented in a checkable manner in fig. 4, input fields of "acquisition channel numbers" behind the items of the three brain function training items may be presented in a white editable state as illustrated, and the like; brain function training items which cannot be executed by the target probe arrangement are presented in a gray-setting manner, for example, a selection box in front of a right motor imagery item, an input field of a collection channel number in back of the right motor imagery item and the like are presented in a gray-setting manner in fig. 4.

In this way, brain function training items which are suitable for the arrangement of the target probes can be provided and presented in the brain function rehabilitation training device 100, so that a user can quickly locate the brain function training items to be executed, and the user experience is improved.

In some embodiments, as shown in fig. 6, the interactive control method further includes steps S211 to S212. After receiving the fourth interactive operation and before receiving the third interactive operation, the interactive control method performs steps S211 to S212.

In step S211, a fifth interactive operation is received in which the user selects a target brain function training program via the acquisition channel setting interface 4.

For example, as shown in fig. 4, brain function training items corresponding to the target near infrared headgear may be presented on the acquisition channel setting interface 4. The brain function training items can be multiple, and the training contents of the subjects to be trained corresponding to different brain function training items are different.

Options of a plurality of brain function training items 43 corresponding to the target near infrared headgear are presented on the acquisition channel setting interface 4. After determining the brain function training items for performing the brain function rehabilitation training, the user may select the target brain function training item to be trained by checking the corresponding brain function training item 43 on the acquisition channel setting interface 4, for example, checking the selection frame on the current face of the corresponding brain function training item bar in fig. 4, so as to achieve the association between the target brain function training item and the target near-infrared headgear actually adopted by the near-infrared data acquisition module 101, so that the training content using the target near-infrared headgear provided by the brain function rehabilitation training device 100 subsequently corresponds to the target brain function training item. The user can select a plurality of interesting brain function training items as target brain function training items at the same time, so that the selection of the target brain function training items of the target near-infrared headgear is completed at one time.

In step S212, in response to the fifth interactive operation, an option of the target brain function training item is presented on the target training item selection interface. The target brain function training program is a brain function training program selected based on a fifth interactive operation.

Illustratively, the interface shown in fig. 7 is specifically the target training item selection interface 7. For example, after the brain function training items corresponding to the target near infrared headgear are selected in fig. 4, that is, the target brain function training items include left motor imagery, attention training, and memory training, only the selected target brain function training items 71 are presented in the subsequent target training item selection interface 7, as shown in fig. 7. When the user wishes to perform the brain function rehabilitation training, the creation task option 72 of the target brain function training item to be performed by the training object is selected on the target training item selection interface 7, for example, a "create task" button in a selection area of the corresponding training item (for example, "left motor imagery") in fig. 7 is clicked to achieve creation of the corresponding training task.

In this way, the target training item selection interface 7 only presents the selected target brain function training items in response to the selection of the target brain function training items by the user in the acquisition channel setting interface 4, and no training items uninteresting by the user are presented in the target training item selection interface 7, so that the selection pressure of the user during the selection of the target training items can be reduced, the working efficiency is increased, and the user experience is improved.

In some embodiments, in a third interactive operation, the number of at least one target acquisition channel in the target probe arrangement is entered in the target acquisition channel setting item 44 corresponding to the brain function training program. Or in the third interactive operation, a target acquisition channel can be selected from the probe arrangement diagram of the target probe arrangement according to the brain function training program; or a probe layout of a target probe arrangement comprising only target acquisition channels may also be introduced.

Illustratively, as shown in fig. 4, in the third interactive operation, an input field for inputting the acquisition channel number may be presented on the acquisition channel setting interface 4, and the user may select a target acquisition channel by inputting the number of the acquisition channel corresponding to the brain region of interest in the input field. Alternatively, in the third interactive operation, a probe arrangement chart of a corresponding target probe arrangement may be presented at the target acquisition channel setting item 44 in correspondence with the brain function training item, and the user may directly select a target acquisition channel (not shown in the figure) on the probe arrangement chart. Furthermore, in the third interactive operation, the target acquisition channel setting item 44 may also be presented as a picture-in item of the probe arrangement diagram associated with the target acquisition channel on the acquisition channel setting interface 4. The user selects a target acquisition channel (not shown in the figure) according to the acquisition channels included on the probe arrangement chart by importing the probe arrangement chart of the target probe arrangement including only the target acquisition channels using the picture import item. Therefore, the target acquisition channel selection method is flexible, and a user can select the most suitable mode from multiple modes according to the situation of the user to select the target acquisition channel.

In addition, the user can select the brain region of interest according to personal experience, but because of individual differences in training effect of the training object, if the user does not know which brain region should be more focused, all acquisition channels can be selected during the first training or the first few training, and according to the feedback brain activation condition changes before and after the brain region of interest training, which brain region is selected as the region of interest in the subsequent training is determined.

In some embodiments, as shown in fig. 4, the acquisition channel setting interface 4 further includes a target acquisition channel picture import item 45 corresponding to the brain function training item. The user may use the target acquisition channel picture import item 45 to import a target acquisition channel picture corresponding to the brain function training program, for example, click on the "modification" corresponding to each training program under the "acquisition channel picture path" in fig. 4, to input a picture path of the target acquisition channel picture and import the target acquisition channel picture, which is the first import operation. In response to the first import operation, a target acquisition channel picture is displayed on the training task creation interface 8. The target acquisition channel picture at least comprises a brain model and probe arrangement which is related to the brain model and comprises a target acquisition channel. For example, if the user imports a picture in the target acquisition channel picture importation item 45 by the first importation operation, the same picture (e.g., the picture in the black frame in fig. 8) is presented on the training task creation interface 8 as shown in fig. 8. In addition, the imported pictures can be the brain model and the probe arrangement which is related to the brain model and contains the target acquisition channel, and can also be other pictures related to brain function training projects, and the specific limitation is not included herein.

Therefore, the user can select the content of the imported pictures according to actual demands, especially the pictures which at least comprise brain models and the probe arrangement of the target acquisition channels which are related to the brain models can be imported, the body feeling of the user can be improved, and the user can further know the brain region concerned by the brain function training program.

In some embodiments, as shown in FIG. 8, the training task creation interface 8 also includes a probe layout display area 81 (e.g., the "acquisition channel" area in FIG. 8) thereon. In the probe layout display area 81, a target probe layout with target acquisition channels marked is displayed.

The target probe layout is a picture of the determined target probe arrangement, and after the user selects a target acquisition channel of the target probe arrangement on the acquisition channel setting interface 4, the original target probe layout is displayed in a probe layout display area 81 on the training task creation interface 8, where the target probe layout may include information marked with a probe number or name and marked with an acquisition channel number or name. And, based on the above-mentioned user-selected target acquisition channels, displaying the target probe arrangement marked with the target acquisition channels on the target probe arrangement chart, for example, highlighting the target acquisition channels in the form of displaying the target acquisition channel mark 82 as in fig. 8 at the target acquisition channels or highlighting the target acquisition channel region (not shown in the figure) to distinguish from other non-target acquisition channels, so that the user further verifies whether the selected target acquisition channels are accurate or not to prevent the selected target acquisition channels from being erroneous, but the activation analysis of the brain region of interest is inaccurate.

In some embodiments, as shown in fig. 9, the interactive control method further includes steps SA1 to SA3.

In step SA1, a sixth interactive operation is received indicating on the training task creation interface 8 that the user is to initiate a training task related to the target brain function training program.

In step SA2, in response to the sixth interactive operation, a start operation of the brain function rehabilitation training by the user is received, and a start signal is sent to the near infrared data acquisition module 101 to enable synchronous start thereof.

In step SA3, in response to the start operation, near infrared data of all acquisition channels arranged by the target probe are acquired by the near infrared data acquisition module 101, feedback content of the target brain function training program is calculated using only the near infrared data of the target acquisition channels, and the feedback content is provided to the training subject.

Specifically, a start-up option of the training task related to the target brain function training item is presented on the training task creation interface 8, and when the user determines that the target brain function training item is to be started to be executed, the start-up option is clicked to start executing the training item. After the training task starts, the near infrared data acquisition module 101 starts to acquire near infrared data of all acquisition channels arranged by the target probe, then calculates the near infrared data by using only the near infrared data of the target acquisition channels, and presents feedback content provided to the training object in the near infrared data of the target acquisition channels, so that a user can acquire brain activation conditions of a brain region of interest of the training object in the process of executing the target brain function training project on a feedback interface. After the training is completed, a rehabilitation training report may be presented on an editing interface of the training report as shown in fig. 10 to feed back brain activation changes before and after the training of the brain region of interest.

In some embodiments, as shown in fig. 11, the interactive control method further includes steps S101 to S102. The interactive control method performs steps S101 to S102 before receiving the first interactive operation.

In step S101, a seventh interactive operation of the user to newly create a near infrared headgear on the near infrared headgear setting interface 3 is received.

For example, as shown in fig. 3, a new headgear option 33 of a new near infrared headgear for realizing brain function rehabilitation training may be presented on the near infrared headgear setting interface 3. In the case where there is no near-infrared headgear that the user wishes to use for performing brain function rehabilitation training in the near-infrared headgear presented on the near-infrared headgear setting interface 3, the user can newly create a near-infrared headgear to be used by selecting a headgear newly creation option 33 for newly creating a near-infrared headgear on the near-infrared headgear setting interface 3.

In step S102, in response to the seventh interactive operation, the new near-infrared headgear information is sent to the near-infrared data acquisition module 101 for acquiring near-infrared data, the new headgear probe arrangement information corresponding to the new near-infrared headgear fed back by the near-infrared data acquisition module 101 is received, and the new headgear probe arrangement information is presented on the acquisition channel setting interface 4. The newly-built head cap probe arrangement information comprises at least one probe arrangement corresponding to the newly-built near-infrared head cap.

Illustratively, in response to the seventh interactive operation, the head cap information input field 41 of the newly-built near-infrared head cap information and the target probe arrangement 42 corresponding to the newly-built near-infrared head cap are presented at the acquisition channel setting interface 4 corresponding to the newly-built near-infrared head cap. The newly built near infrared headgear information comprises names, numbers and the like of the near infrared headgear. When the user inputs new near-infrared headgear information in the headgear information input field 41, the brain function rehabilitation training device 100 transmits the new near-infrared headgear information to the near-infrared data acquisition module 101 that acquires near-infrared data, and receives new headgear probe arrangement information corresponding to the new near-infrared headgear fed back by the near-infrared data acquisition module 101. Each near infrared headgear and its probe arrangement information are pre-stored in a memory of the near infrared data collection module 101 in a corresponding manner.

In the case that only one probe arrangement is included in the newly-built head cap probe arrangement information, the probe arrangement is directly determined as a target probe arrangement of the newly-built near-infrared head cap and is presented at the target probe arrangement 42 on the acquisition channel setting interface 4. At this time, the target probe arrangement 42 of the newly built near infrared headgear on the acquisition channel setup interface 4 assumes a non-editable state such as gray placement. In the case where a plurality of probe arrangements are included in the newly built head cap probe arrangement information, the target probe arrangement 42 of the newly built near infrared head cap on the acquisition channel setting interface 4 assumes an editable state, for example, the target probe arrangement 42 under the "SD name" in fig. 4 becomes a white editable state as illustrated. The user may select a target probe arrangement to be used by utilizing the target probe arrangement 42.

Further, as shown in fig. 3. A headgear deletion option 34 for each type of near infrared headgear may be presented on the near infrared headgear setup interface 3. The user can delete the near infrared headgear added by user, but can not delete the near infrared headgear carried by the system. When the user performs the deleting operation on the self-defined near-infrared head cap, a secondary confirmation popup window is presented to confirm that the user really needs to perform the deleting operation on the near-infrared head cap.

In some embodiments of the present application, there is provided a brain function rehabilitation training device 100, comprising at least a processor configured to perform an interactive control method for the brain function rehabilitation training device 100 according to various embodiments of the present application.

Specifically, the brain function rehabilitation training device 100 adopting the interactive control method can enable a user to select a collection channel for collecting near infrared data arranged by a target probe after selecting a target near infrared headgear by setting a brain region of interest in the brain function rehabilitation training device 100 before a training object executes a brain function training program, the selected collection channel is processed into a target collection channel for the brain region of interest, and feedback content is provided for the training object based on the near infrared data of the target collection channel when a subsequent training object executes the brain function training program, for example, the change of a main body related to the activation condition of the brain region of interest and the change of the activation condition of the brain region of interest before and after training are fed back to the user, thereby meeting the requirement that the user hopes to know the brain activation condition of the brain region of interest. The above-mentioned mode of user design brain district of interest easy operation, convenient and with low costs, can freely select the target acquisition channel according to the demand to the brain district of interest to the user knows the brain function situation of training object and in time adjusts training or treatment strategy, and the flexibility is strong, need not the user again to customize the headgear of different probe arrangements according to the demand, for example can utilize the headgear of a probe arrangement to select the target acquisition channel of arbitrary combination as the brain district of interest, and in the training process, brain function rehabilitation training device 100 calculates the training result of brain district of interest through the near-infrared data that only uses the target acquisition channel, compare with the condition that can't select the acquisition channel, reduce the scale with the mode that suits with the acquisition channel quantity, thereby can improve the training result feedback efficiency of brain function rehabilitation training device 100.

In some embodiments of the present application, a storage medium is provided, storing a computer program that when executed by a processor implements an interactive control method for a brain function rehabilitation training device 100 according to various embodiments of the present application.

Note that according to various units in various embodiments of the present application, they may be implemented as computer-executable instructions stored on a memory, which when executed by a processor, may implement corresponding steps; may also be implemented as hardware having corresponding logic computing capabilities; and may also be implemented as a combination of software and hardware (firmware). In some embodiments, the processor may be implemented as any one of FPGA, ASIC, DSP chip, SOC (system on a chip), MPU (e.g., without limitation, cortex), etc. The processor may be communicatively coupled to the memory and configured to execute computer-executable instructions stored therein. The memory may include read-only memory (ROM), flash memory, random Access Memory (RAM), dynamic Random Access Memory (DRAM) such as Synchronous DRAM (SDRAM) or Rambus DRAM, static memory (e.g., flash memory, static random access memory), etc., upon which computer-executable instructions are stored in any format. Computer-executable instructions may be accessed by the processor, read from ROM or any other suitable memory location, and loaded into RAM for execution by the processor to implement a wireless communication method in accordance with various embodiments of the present application.

It should be noted that, among the components of the system of the present application, the components thereof are logically divided according to functions to be implemented, but the present application is not limited thereto, and the components may be re-divided or combined as needed, for example, some components may be combined into a single component, or some components may be further decomposed into more sub-components.

Furthermore, although exemplary embodiments have been described herein, the scope thereof includes any and all embodiments having equivalent elements, modifications, omissions, combinations (e.g., of the various embodiments across schemes), adaptations or alterations based on the present disclosure. Elements in the claims are to be construed broadly based on the language employed in the claims and are not limited to examples described in the present specification or during the practice of the present application, which examples are to be construed as non-exclusive. It is intended, therefore, that the specification and examples be considered as exemplary only, with a true scope and spirit being indicated by the following claims and their full scope of equivalents.

The above description is intended to be illustrative and not restrictive. For example, the above-described examples (or one or more aspects thereof) may be used in combination with each other. For example, other embodiments may be used by those of ordinary skill in the art upon reading the above description. In addition, in the above detailed description, various features may be grouped together to streamline the disclosure. This is not to be interpreted as an intention that the disclosed features not being claimed are essential to any claim. Rather, the subject matter of the present application is capable of less than all of the features of a particular disclosed embodiment. Thus, the following claims are hereby incorporated into the detailed description as examples or embodiments, with each claim standing on its own as a separate embodiment, and it is contemplated that these embodiments may be combined with one another in various combinations or permutations. The scope of the application should be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled.

Claims (11)

1. An interactive control method for a brain function rehabilitation training device, wherein the brain function rehabilitation training device provides a brain function training program for a training object and provides feedback content to the training object based on near infrared data of the training object, the interactive control method comprising, in a case where the training object is ready to execute the brain function training program:

receiving a first interactive operation of setting a target near-infrared head cap to be used by a user through a near-infrared head cap setting interface, wherein the target near-infrared head cap corresponds to at least one probe arrangement;

receiving a second interactive operation of a user aiming at the target near-infrared headgear indication to select a target acquisition channel;

responding to the first interactive operation and the second interactive operation, presenting an acquisition channel setting interface corresponding to the target near infrared headgear, wherein the acquisition channel setting interface at least comprises target probe arrangement, brain function training items and target acquisition channel setting items;

and receiving a third interactive operation of selecting a target acquisition channel from the target acquisition channel setting items corresponding to the brain function training items by a user, wherein the target acquisition channel is selected from at least part of acquisition channels in the target probe arrangement, and providing feedback content for a training object based on near infrared data of the target acquisition channel when the training object executes the brain function training items.

2. The interactive control method according to claim 1, wherein the interactive control method further comprises:

and before receiving the third interaction operation, receiving a fourth interaction operation of determining the target probe arrangement by the user through the acquisition channel setting interface, wherein the target probe arrangement is selected from at least one probe arrangement corresponding to the target near-infrared headgear.

3. The interactive control method according to claim 2, wherein the interactive control method further comprises:

and responding to the four interactive operations, presenting brain function training items which are suitable for the target probe arrangement on the acquisition channel setting interface, or selecting only brain function training items which are suitable for the target probe arrangement from the presented brain function training items and editing the corresponding target acquisition channel setting items.

4. The interactive control method according to claim 2, wherein the interactive control method further comprises:

after receiving the fourth interactive operation and before receiving the third interactive operation, receiving a fifth interactive operation of selecting a target brain function training item by the user via the acquisition channel setting interface, the target brain function training item being selected from at least one brain function training item corresponding to the target near infrared headgear;

And responding to the fifth interaction operation, presenting options of target brain function training items on a target training item selection interface, wherein the target brain function training items are brain function training items selected based on the fifth interaction operation.

5. The interactive control method according to claim 1, wherein the third interactive operation includes:

inputting the number of at least one target acquisition channel in the target probe arrangement in the target acquisition channel setting item corresponding to the brain function training item;

or alternatively, the first and second heat exchangers may be,

selecting the target acquisition channel from the probe arrangement diagram of the target probe arrangement according to the brain function training program;

or alternatively, the first and second heat exchangers may be,

a probe layout map of the target probe arrangement including only the target acquisition channels is imported.

6. The interactive control method according to claim 1, wherein the acquisition channel setting interface further comprises a target acquisition channel picture import item corresponding to the brain function training item,

and responding to a first importing operation of importing the target acquisition channel picture corresponding to the brain function training item by the user by utilizing the target acquisition channel picture importing item, and displaying the target acquisition channel picture on a training task creation interface, wherein the target acquisition channel picture at least comprises a brain model and probe arrangement of the target acquisition channel which is presented in association with the brain model.

7. The interactive control method according to claim 6, wherein the training task creation interface further includes a probe layout display area in which a target probe layout marked with the target acquisition channel is displayed.

8. The interactive control method according to any one of claims 1 to 7, wherein the interactive control method further comprises:

receiving a sixth interactive operation of a user on the training task creation interface, wherein the sixth interactive operation indicates that a training task related to the target brain function training project is to be started;

responding to the sixth interactive operation, receiving the starting operation of the user on brain function rehabilitation training, and sending a starting signal to the near infrared data acquisition module so as to synchronously start the near infrared data acquisition module;

and responding to the starting operation, collecting near infrared data of all acquisition channels arranged by the target probe through the near infrared data acquisition module, calculating feedback content of the target brain function training program by using only the near infrared data of the target acquisition channels, and providing the feedback content for a training object.

9. The interactive control method according to any one of claims 1-7, wherein the interactive control method further comprises, prior to receiving the first interactive operation:

Receiving a seventh interactive operation of newly building a near infrared headgear on the near infrared headgear setting interface by a user;

responding to the seventh interactive operation, sending new near-infrared head cap information to a near-infrared data acquisition module for acquiring the near-infrared data, receiving new head cap probe arrangement information corresponding to the new near-infrared head cap fed back by the near-infrared data acquisition module, and displaying the new head cap probe arrangement information on an acquisition channel setting interface, wherein the new head cap probe arrangement information comprises at least one probe arrangement corresponding to the new near-infrared head cap.

10. A brain function rehabilitation training device comprising at least a processor configured to perform the interactive control method for a brain function rehabilitation training device according to any one of claims 1 to 9.

11. A storage medium storing a computer program, wherein the computer program when executed by a processor implements the interactive control method for a brain function rehabilitation training device according to any one of claims 1 to 9.