SYSTEM AND METHOD FOR NEUROFEEDBACK TRAINING THAT UTILIZES ANIMAL IN THE FEEDBACK LOOP

Abstract

The invention discloses a method of operating a system for neurofeedback (NFB) that includes trained animal in a feedback chain. Feedback chain consists of the following steps:

A->B->C->D->A wherein said steps are: A. real time recording of the subject's EEG performed by the user module and forwarded to the mobile module; B. analytics of the recorded signal performed by the mobile module and algorithmic decisioning about the stimulation form; C. forwarding the stimulation towards the animal by using of one or more ultrasonic speakers simultaneously wherein the information needed for the animal performance is forwarded in the form of a coded ultrasonic signal; and D. performing of a learned action by the animal triggered by the received ultrasonic signal from the step C which provides a stimulus to the subject exposed to the NBF training.

Claims

1-11. (canceled)

12. A method of operating a system for neurofeedback (NFB) training on a subject that includes an animal species in a feedback chain; wherein the system comprises at least one user module, a mobile module and optionallyoption modules selected from one or more separated modules placed in a NFB performance area and animal modules placed on an animal; wherein the user module is equipped with: a set of electroencephalographic (EEG) electrodes for brainwave recording, an EEG amplifier, a data processing unit that transforms EEG signals to electronic information suitable for a wireless transfer, a pairing unit that enables connectivity with other units, and an ultrasonic speaker for communication with the animal; wherein the mobile module is equipped with a data processing unit that processes received EEG signals of one or more subjects, a pairing unit that enables connectivity with other units; an animal training unit, a control unit, and an internet connection with data cloud all connected with the data processing unit; wherein said each option module is equipped with a corresponding data processing unit, a pairing unit, and an ultrasonic speaker for communication with an animal; wherein the neurofeedback training on subject is performed by the system in which said feedback chain consists of the steps:
A->B->C->D->A where the steps include: A. real time recording of the subject's EEG performed by the user module and forwarded to the mobile module by using their respective paired units; B. analytics of the signal recorded in the step A performed by the data processing unit of the mobile module, and algorithmic decisioning about the stimulation form for the subject whose EEG signal has been recorded; C. forwarding the stimulation form for the subject determined in the step B towards the animal; and D. performing an action by the animal, triggered by the stimulation, which provides a stimulus to the subject exposed to the neurofeedback training of the step A; characterized by that the used animal species are previously trained canine species or dolphin species, susceptible to the ultrasound, which are the only source of visual, tactile or auditory stimulus to the subject; wherein the information needed for the animal performance, creating the stimulus for the subject, is forwarded in the form of a coded ultrasonic signal via one or more ultrasonic speakers simultaneously, placed on one or more modules selected from: the user module, the separated module and animal module; wherein all of said modules are paired with the mobile module.

13. The method according to the claim 12, characterized by that, the mobile module is wearable and situated on the subject and is optionally merged with the user module over which any changes to the NFB training, monitoring and intervention are performed via the Internet connection with the data cloud.

14. The method according to claim 12, characterized by that, the pairing units are short-range communication units.

15. The method according to claim 12, characterized by that, in order to provide communication in the step C the ultrasonic speaker that emits ultrasonic signals to the animal is placed in the user module.

16. The method according to claim 12, characterized by that, in order to provide communication in the step C the ultrasonic speaker that emits ultrasonic signals to the animal is placed in the animal module that is noninvasively placed on the animal in the form of collar or a patch; wherein the mobile module controls the ultrasonic signal from the ultrasonic speaker.

17. The method according to claim 12, characterized by that, in order to provide communication in the step C the ultrasonic speaker is placed in a separated module placed in the space; wherein the mobile module controls the ultrasonic signal from the ultrasonic speaker.

18. The method according to claim 12, characterized by that, the link between the mobile module and the option module and ultrasonic speakers of option modules are used to train the selected animals.

19. The method according to claim 12, characterized by that, one or more mobile modules simultaneously processes information from the step A for multiple users in order to control multiple animals in a way that each animal is trained for a different set of ultrasonic commands, enabling simultaneous independent NFB trainings in the same space without interference.

20. A communication system for conducting NFB training on the subject that includes other trained animal species, characterized by that the communication system comprises means for performing the method according to claim 12.

21. The communication system for conducting NFB training on the subject according to claim 20, characterized by that: the user module and the mobile module combined make one new module without the control unit, wherein the control of created new module is conducted exclusively by means of the data cloud, and wherein that new module can be paired with any said option module.

Description

DESCRIPTION OF THE FIGURES

[0035] FIG. 1 represents prior art regarding NFB wherein as a source of stimuli is a display on which the content that affects or alters subject's EEG patterns is displayed.

[0036] FIG. 2 represents NFB setup according the said invention in which other animal species are used in the feedback chain; letters A, B, C and D denote steps explained in the previous section.

[0037] FIG. 3 represents one version of the wearable user module.

[0038] FIG. 4 represents the animals controlled by ultrasound via using, so called, a separated module and the module attached to an animal.

[0039] FIG. 5 represents different types of brainwaves that are sampled by the user module and the hardware integrated in the user module.

[0040] FIG. 6 represents a diagram of mobile module hardware, while drawings 7 and 8 represent the diagram of the separated module and the animal module.

[0041] FIG. 9 represents NFB implemented through the use of user module and mobile module, while

[0042] FIG. 10 represents NFB implemented by the use of user module, mobile module and the module that is placed on the trained animal.

[0043] FIG. 11 represents NFB performed by means of user module, mobile module and separated module.

[0044] FIG. 12 shows multiple NFBs realized between subject-animal pairs wherein all the control is performed by a single mobile module.

[0045] FIG. 13 shows one variant of the invention where the user module and the mobile module are integrated in a single module.

[0046] FIG. 14 represents the use of such all-in-one module for NFB.

DETAILED DESCRIPTION OF ONE EMBODIMENT OF THE INVENTION

[0047] As already mentioned in previous sections, a NFB is a noninvasive method that improves brain functioning when used over a period of time. Historically, it dates back in 1924 when psychiatrist Hans Berger connected, by means of noninvasive electrodes, patients scalp to a galvanometer and made the first recording of brainwaves. Development of measurement methods and improved hardware enabled discoveries and subsequent classification of brainwaves according to their frequency ranges; see FIG. 5. Today we distinguish the following waves: delta waves from 0.2-3 Hz, theta waves from 3-8 Hz, alpha waves from 8-12 Hz, beta waves from 12-27 Hz and gamma waves from 27-100 Hz.

[0048] In the last decade NFB is being used for treatments ranging from ADHD to alcoholism. More information can be found in the review: D. Corydon Hammond, PhD, ABEN, QEEG-D An Introduction to Neurofeedback; available at: http://www.appliedneuroscience.org.au/neurotherapy

[0049] Traditionally, NFB is conducted as shown in FIG. 1: the treated subject (100) has on his head the user module (10) equipped with electrodes (11). The user module (10) is connected, usually by wire and since recently wirelessly, with the mobile module (20). The purpose of the user module (10) is to ensure reliable acquisition of the subject's EEG activity and transfer it to the mobile module (20) for further processing. The mobile module (20) or it's technical equivalentstationary device (20)processes received signals and, according to the preprogrammed scenario, displays, on the computer screen (60), images, video, and produces sound or some other stimulus, e.g. tactilethat the subject (100) can perceive. Neurological activity induced in the process changes the subject's (100) EEG patterns in a desired way. This is the traditional, i.e. standard, way to make the NFB communication loop closed; step A in FIG. 1 represents forwarding of the EEG recordings to the module (20), step B represents analytics of the received EEG signal, step C represents a generation of the stimulus according to the analytics performed in step B, while step D is a transfer of formed stimulus to the subject (100).

[0050] The main difference between the disclosed invention and the traditional NFB is the fact that one element of the feedback loop is a trained animal (101, 102); susceptible to ultrasonic stimuli. The difference can clearly be seen in FIG. 2; the user module (10) is equipped with EEG electrodes (11) placed on the scalp, where one of possible configurations is shown in FIG. 3. The user module (10) is connected, usually by wire and since recently wirelessly, with the mobile module (20). The mobile module (20) or his technical equivalentstationary device (20)processes received signals and, according to the preprogrammed scenario in one embodiment of disclosed invention, returns information about the stimulation or activation of the animal to the user module (10). The user module (10) activates ultrasonic speaker (15) and directs ultrasonic command to the previously trained animal (101, 102), e.g. dog. On the basis of the received ultrasonic command, the dog performs a trick that is visual, e.g. chases his own tail; or tactile, e.g. approaches to the subject (100) and cuddles; or auditorybarks. Such behavior of the animal (101, 102) is used for the NFB and produces changes in the subject's (100) EEG signal that is acquired by means of electrodes (11). Such signal is subsequently used to produce the next signal in the user module (10). In this way the NFB loop is completely closed, according to the said invention.

[0051] There are numerous advantages of this kind of NFB's implementation; the NFB in not limited to the closed performance arena, the produced live animal feedback has significant impact on the subject's EEG that is more intensive when compared with the feedback produced by watching images on the screen (60) as is the case in traditional NFB implementation. The only significant drawback is that NFB implementation according to presented invention requires trained animal (101, 102). Especially suitable species susceptible to ultrasonic commands are canines, i.e. dogs; as well as dolphins and whales that communicate in the ultrasonic range also. For other suitable animal species details can be found here: https://en.wikipedia.org/wiki/Hearing_range

[0052] In case that performance area is a large open space it is useful to use additional modules for generation of ultrasonic signals; e.g. underwater modules for dolphins/whales or external modules in large parks for dogs. Each additional module can be separated standalone module (30), or an animal module (40) that is noninvasively placed on the trained animal (101, 102). It can be formed as a dog collar; or a sticky patch for dolphins or whales. It is worth to note that mentioned modules should not prevent animals in their natural behavior within given environment. The number of these option modules is arbitrary.

[0053] As already mentioned, NFB implementation according to the presented invention uses trained animal in the feedback loop. The prior art document CN104049979 teaches about one way to train for NFB. As mentioned before, the response to ultrasonic commands must be fully individualized; i.e. each animal should have its own set of coded commands which in turn enables simultaneous conduction of NFB of many subjects (10) in the same performance area.

[0054] FIG. 5 shows in detail one possible construction of the user module (10). It has helmet-like shape and size such that it can be put on the head so that EEG electrodes (11) fit well on the subject's (100) head and touch the subject's (100) skin in a way that the subject's (100) brainwaves can be recorded. The signal from one or more EEG electrodes (11), usually less than 100 pV, is led to an EEG amplifier (12) in order to be processed by data processing unit (13). The data processing unit (13) converts that signal to digital record by means of analog-to-digital converter; or, even better, convert it to pulse-width-modulated wireless signal. Such system, specially adapted for energy efficient transmission of EEG signals, is disclosed in the European patent EP3005570B1 with the title ENERGY-EFFICIENT SYSTEM FOR DISTANT MEASUREMENT OF ANALOGUE SIGNALS; filed in the name of Sveuciliste u Osijeku, Fakultet elektrotehnike, . . . .

[0055] Once digitalized, or analogously modulated, EEG signal can be, by means of the pairing unit (14), transferred to the mobile unit (20), i.e. it's pairing unit (25). Examples of good pairing means are: asynchronous UWB (ultrawideband) communication, any communication protocol used for IoT (Internet of Things) or well-known Bluetooth modules. The main problem of the present communication is energy efficiency that reflects to the power supply (16) autonomy, without which the user module (10) becomes useless. It should be noted that it is favorable that all the pairing units (14) use duplex communication; which is not a necessary condition but certainly an advanced design.

[0056] FIG. 6 shows one embodiment of the mobile module (20) or it's stationary technical equivalent. The term mobile relates to the fact that it is the size of a mobile ultra-book, with work autonomy of about 10 hours, and is used by a therapist/technician to perform or supervise the NFB for example in nature, where the animal (101, 102), e.g. the dog, that is a part of the feedback loop, is located. That mobile module (20) is in one embodiment a modified ultrabook or a smartphone, that is at the same time the data processing unit (23), while the pairing unit (24) depends on the choice of the user module (10). Namely, if the user module (10) uses Bluetooth for communication with the mobile module (20), then the pairing unit (24) is a part of the data processing unit (23). Data processing unit (23) comprises or can access animal modules (27) that are usually composed of programming code and instructions for animal training. Mobile module (20) can be connected to the data cloud (50) via standard internet connection (29). In practice, additional parallel analysis can be made in the data cloud (50); each NFB subject (100) can be monitored and the CRM (customer relation management) can be provided. Mobile module (20) is equipped with the control unit (28) that can be implemented as a touch screen, by means of which the person supervising NFB can influence the behavior of the animal (101, 102) regardless of the performed analytics on the subject's (100) EEG pattern. The power supply (26) is usually integrated with the data processing unit (23) that is a solution which is common in the art.

[0057] FIGS. 7 and 8 show the embodiment of the optional modules that can be implemented as the standalone separated module (30), or the animal module (40). The both modules are built similarly, animal module (40) being smaller and fit for mounting on the animal (101, 102). Each of the mentioned optional modules (30, 40) contains the pairing unit (34, 44) by which it can be paired with the mobile module (20) and/or the user module (10) according to the configuration chosen by the NFB operator. Data processing unit (33, 43) translates received instruction to the ultrasonic signal that is subsequently emitted by the ultrasonic speaker (35, 45) to the chosen animal (101, 102). Power supplies (36, 46) ensure the anatomy of the mentioned devices for a period of couple of hours.

[0058] Some of possible embodiments are shown in FIG. 9-12.

[0059] FIG. 9 shows the basic configuration where NFB is performed in 4 steps closed into a loop, as shown below:

A->B->C->D->A

where: [0060] A. represents real time recording of the subject's (100) EEG performed by the user module (10) and forwarded to the mobile module (20) by using their respective paired units (14, 24); [0061] B. analytics of the signal recorded in the step A., performed by the data processing unit of the mobile module (23), and algorithmic decisioning about the stimulation form for the subject (100) whose EEG signal has been recorded; [0062] C. forwarding the stimulation form for the subject (100) determined in the step B. towards the animal (101, 102) includes, according to this embodiment, forwarding of instructions of stimulation to the paired user module (10) that performs activation of its ultrasonic speaker (15) by which the required information is emitted to the animal (101, 102) in the form of coded ultrasonic signal; and [0063] D. performing of a learned action by the animal (101, 102) triggered by the received ultrasonic signal from the step C. which provides a stimulus to the subject (100) exposed to the neurofeedback training of the step A.

[0064] Step D->A closes the loop of the said NFB.

[0065] In yet another embodiment according to the invention shown in FIG. 10, in the step C. signal travels directly to the paired optional animal module (40) that uses ultrasonic speaker (45) in order to transfer the needed information to the animal (101, 102). In this embodiment, a consistent connection to animal is established, regardless of the distance between the animal and the subject (100) or the mobile module (20).

[0066] In yet another embodiment according to the invention shown in FIG. 11, in the step C. the signal travels directly to the paired separated module (30) which uses its ultrasonic speaker (35) to transfer the needed information to the animal. In this embodiment, a consistent connection to the animal is again established. In case when the medium is water and the animal is dolphin (102), the preferred position of the ultrasonic speaker (35) is a submerged position.

[0067] FIG. 12. shows example of multiuser interface connected to one mobile module (20). The situation for each subject (100, 100, 100, . . . ) is identical to the one previously described for FIG. 9. Yet, in this case one mobile module (20) is connected via link (L1, L2, L3, . . . ) by the use of the pairing unit (24) with the series of pairing units (14, 14, 14, . . . ) placed within user modules (10, 10, 10, . . . ). Each independent user module (10, 10, 10, . . . ) controls one ultrasonic signal (S1, S2, S3, . . . ) emitted from the ultrasonic speaker (15, 15, 15, . . . ) in order to control the animal (102, 102, 102, . . . ) of one of NFB, NFB, NFB, . . . . Namely, one mobile module (20) has sufficient processor power to serve almost any given number of user modules. This configuration is very convenient when there are more subjects in the same NFB performance area.

[0068] In yet another embodiment according to the invention, the mobile module (20) and the user module (10) are integrated into one module; see FIG. 13. In this integrated module the data processing is performed and animal module (27) as well as the data cloud internet connection (29) is also added. The mentioned internet connection to the data cloud is used for control of such an integrated module. In this case NFB looks as shown in FIG. 14, yet different ways of pairing with optional modules (30, 40) are possible as well as pairing with other user modules (10, 10, . . . ) which is obvious to an average person skilled in the art. The number of possible combinations according to the invention are sufficiently large enough that any operator/supervisor can choose the optimal way to perform NFB on a subject (100).

INDUSTRIAL APPLICABILITY

[0069] The industrial applicability of this invention is obvious, presented invention discovers method of implementation of NFB on the subject (100) that includes other trained animal species (101, 102) in the feedback chain, as well as the system for neurofeedback (NFB) training itself.

REFERENCES

[0070] 10 User module [0071] 11 EEG electrode [0072] 12 EEG amplifier [0073] 13 Data processing unit [0074] 14 Pairing unit [0075] 15 Ultrasonic speaker [0076] 16 Power supply [0077] 20 Mobile module [0078] 23 Data processing unit [0079] 24 Pairing unit [0080] 26 Power supply [0081] 27 Animal training unit [0082] 28 Control unit [0083] 29 Data cloud internet connection [0084] 30 Separated module [0085] 33 Data processing unit [0086] 34 Pairing unit [0087] 35 Ultrasonic speaker [0088] 36 Power supply [0089] 40 Animal module [0090] 43 Data processing unit [0091] 44 Pairing unit [0092] 45 Ultrasonic speaker [0093] 46 Power supply [0094] 50 Data cloud [0095] 60 Screen [0096] 100 Subject [0097] 101 Dog [0098] 102 Dolphin [0099] S Ultrasonic signal [0100] L Established link