Description:FIELD OF THE INVENTION

[0001] The present invention relates to artificial intelligence-integrated swimming assistive system for real-time learning, stress monitoring, and emotional wellness, that provides real-time guidance for swimming, monitors physical movements to prevent injury, and tracks emotional stress for overall well-being.

BACKGROUND OF THE INVENTION

[0002] Swimming is a widely practiced physical activity known for its health benefits, including improved cardiovascular fitness, muscle strength, and stress relief. It is often recommended for both recreational and therapeutic purposes. Learning to swim and improving technique requires consistent practice, physical coordination, and guidance. In recent years, there has been growing interest in integrating technology with training methods to enhance learning outcomes and monitor physical and emotional health during physical activities such as swimming.

[0003] Traditionally, swimming training relies heavily on manual coaching, where instructors provide verbal or visual guidance from outside the pool. Correction of technique is often delayed, as feedback is given only after observing the swimmer over a period of time. Monitoring of stress, fatigue, or emotional response is generally not included in standard swimming training, and swimmers must self-report their comfort or strain levels. This lack of real-time data limits personalized training and may lead to improper technique development or overexertion.

[0004] Existing methods also involve the use of basic wearables like fitness bands or swim watches to track performance metrics such as lap count or heart rate. However, these systems do not offer in-depth assistance for stroke correction, stress monitoring, or emotional well-being. They are not capable of providing immediate guidance or personalized support during swimming practice. As a result, there is a gap in current systems where real-time, intelligent assistance is missing, and swimmers, especially beginners or individuals with special needs, may not receive the timely support they require.

[0005] US11037545B2 discloses a smart and scalable dementia assistant device is provided that converses with a patient in voices familiar with the patient. It utilizes content learned from the patient and content provided by family, friends, caregivers, and doctors, and autonomously adjusts conversations based on the changing state of the patient's dementia state. The device autonomously controls IoT devices (e.g. doors, elevators, toss, medical dispensers) to help and assist the dementia patient using oral and IoT sensors.

[0006] KR20210069518A discloses a device to detect the motion of a person performing an exercise using an exercise device through a display equipped with a human body motion detection system using AI and a camera for detecting motion to be able to exercise efficiently through an exercise method suitable for one's body type. That is, the present invention is composed of a display equipped with a human body motion detection system using AI and a camera for detecting motion. Accordingly, the present invention has the effect of performing an effective exercise through an exercise method suitable for a body type when exercising using an exercise device.

[0007] Conventionally, many systems are available for assisting in swimming. However, the cited inventions exhibit certain limitations such as the absence of features specifically designed for swimming stroke correction, real-time emotional and stress monitoring, and interactive guidance during swimming activity. These systems are either focused on general fitness or healthcare assistance and do not offer a comprehensive solution combining learning support, physiological monitoring, and emotional wellness specifically tailored to the needs of swimmers in a real-time aquatic environment.

[0008] In order to overcome the aforementioned drawbacks, there exists a need in the art to develop a system that requires to be capable of providing real-time assistance during swimming practice by offering stroke correction, stress and emotional monitoring, and interactive learning support. The system should also be capable of delivering personalized guidance based on user-specific inputs and physiological feedback, thereby enhancing training outcomes.

OBJECTS OF THE INVENTION

[0009] The principal object of the present invention is to overcome the disadvantages of the prior art.

[0010] An object of the present invention is to develop a system that is capable of providing real-time swimming guidance to users in view of learning and practicing different swimming strokes more accurately, thus improving learning speed.

[0011] Another object of the present invention is to develop a system that is capable of continuously monitoring the physical effort and movement of the user during swimming to improve coordination and prevent injuries, thus reducing the risk of muscle strain or injury due to overexertion or incorrect posture.

[0012] Another object of the present invention is to develop a system that is capable of tracking and managing the user’s emotional and stress levels, thereby supporting overall mental wellness and avoid emotional discomfort or stress could affect performance or health.

[0013] Yet another object of the present invention is to develop a system that allows the swimmers to receive immediate feedback and support during practice for faster and safer improvement, thereby helping them to correct mistakes right away, learn faster, and swim more confidently and safely.

[0014] The foregoing and other objects, features, and advantages of the present invention will become readily apparent upon further review of the following detailed description of the preferred embodiment as illustrated in the accompanying drawings.

SUMMARY OF THE INVENTION

[0015] The present invention relates to an artificial intelligence-integrated swimming assistive system for real-time learning, stress monitoring, and emotional wellness that offers real-time swimming guidance. In addition, the system is also capable of enhancing stroke accuracy, and speeding up the learning process along with making corrections during practice, promoting safer, faster, and more confident skill development.

[0016] According to an embodiment of the present invention, artificial intelligence-integrated swimming assistive system for real-time learning, stress monitoring, and emotional wellness, comprising a wearable body configured to be worn over the user’s upper body, a pair of motorized rollers integrated with straps on the front of the wearable are dynamically adjusted by an inbuilt microcontroller to secure the wearable over the user’s torso, the torso dimensions are detected using an ultrasonic sensor, which is synchronized with an artificial intelligence based imaging unit that captures and processes images of the user’s torso, a user interface installed in a wirelessly connected computing unit allows the user to input their medical and physiological information, this data is processed by the microcontroller and stored in a linked database that is configured to create and update a personalized health profile, a hemispherical hydrophobic member is mounted at the collar portion of the wearable, intended to be worn on the user’s head to prevent water from reaching the hair. this member includes an inflatable lining that inflates via the microcontroller to ensure a snug fit, enabling accurate EEG sensor readings, the EEG sensor monitors real-time stress levels and logs them into the user’s health profile for long-term tracking, a microphone installed on the wearable allows the user to give voice commands for selecting the swimming stroke they wish to practice. these commands are processed to activate a holographic projection unit that visually demonstrates the chosen stroke in 3D, a motion sensor, synced with the imaging unit, monitors the user’s movements, and if a deviation is detected, the microcontroller triggers a speaker to deliver corrective voice instructions.

[0017] According to another embodiment of the present invention, the system further includes a dual cardan joint within the shoulder and collar areas to allow controlled movement of the wearable relative to the user's arms, this delivers a resistance force during arm movement in the water, providing strength conditioning, the resistance is adjusted in real time using feedback from a force sensor and a strain sensor to ensure safe exertion levels, a processing unit of a pair of curved fins including curved plate attached with a motorized hinge joint, upon detection of suboptimal arm stroke execution, the microcontroller communicates with the processing unit to actuate the hinge joint that is activated by the microcontroller to provide controlled converging/diverging movement to the fins for improving foot movement and coordination with the arm strokes, thus facilitating in enhanced and effective swimming practice, additionally, multiple flaps are mounted along the arms of the wearable. These open and close with the user’s strokes to optimize motion, if poor arm strokes are detected, the microcontroller works with curved motorized fins to improve foot movement and ensure synchronized arm-foot coordination, enhancing overall swimming efficiency, the motorized rollers are further equipped to adjust tightness based on real-time feedback from flex sensors and user voice commands for optimal comfort, a pair of L-brackets with motorized bristles can extend from the collar area to massage the ears if discomfort is detected through facial expressions, The system's user interface also supports communication with authorized doctors, sharing real-time updates on the user’s emotional and stress levels and receiving alerts in emergencies, the EEG sensor transmits stress data to the interface to track stress trends over time, vibration modules embedded in the arms and feet deliver haptic feedback when poor coordination is detected, the system’s microcontroller is wirelessly connected to the database that is configured for allowing the storage and analysis of session data, including performance metrics, stress indicators, and stroke corrections providing valuable insights for medical professionals and swim coaches.

[0018] While the invention has been described and shown with particular reference to the preferred embodiment, it will be apparent that variations might be possible that would fall within the scope of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

[0019] These and other features, aspects, and advantages of the present invention will become better understood with regard to the following description, appended claims, and accompanying drawings where:
Figure 1 illustrates a perspective view of an artificial intelligence-integrated swimming assistive system for real-time learning, stress monitoring, and emotional wellness.

DETAILED DESCRIPTION OF THE INVENTION

[0020] The following description includes the preferred best mode of one embodiment of the present invention. It will be clear from this description of the invention that the invention is not limited to these illustrated embodiments but that the invention also includes a variety of modifications and embodiments thereto. Therefore, the present description should be seen as illustrative and not limiting. While the invention is susceptible to various modifications and alternative constructions, it should be understood, that there is no intention to limit the invention to the specific form disclosed, but, on the contrary, the invention is to cover all modifications, alternative constructions, and equivalents falling within the spirit and scope of the invention as defined in the claims.

[0021] In any embodiment described herein, the open-ended terms "comprising," "comprises,” and the like (which are synonymous with "including," "having” and "characterized by") may be replaced by the respective partially closed phrases "consisting essentially of," consists essentially of," and the like or the respective closed phrases "consisting of," "consists of, the like.

[0022] As used herein, the singular forms “a,” “an,” and “the” designate both the singular and the plural, unless expressly stated to designate the singular only.

[0023] The present invention relates to an artificial intelligence-integrated swimming assistive system for real-time learning, stress monitoring, and emotional wellness that provides an automated means for swimmers with live guidance for stroke improvement. Furthermore, the developed system is also capable of monitoring physical strain to prevent posture-related injuries, and tracks emotional states to support mental health, thereby ensuring faster learning, improved coordination, and a safer swimming experience for users of all levels.

[0024] Referring to Figure 1, a perspective view of an artificial intelligence-integrated swimming assistive system for real-time learning, stress monitoring, and emotional wellness is illustrated, comprising a wearable body 101 having a pair of motorized rollers 102 installed on a front portion of the body 101, an artificial intelligence-based imaging unit 103 installed on the body 101, a microphone 104 installed on the body 101, a holographic projection unit 105 installed on the body 101, a speaker 106 mounted on the body 101, a hemispherical hydrophobic member 107 integrally mounted at collar portion of the body 101, a dual cardan joint 108 integrated within shoulder and collar portions of the body 101, a plurality of flaps 109 mounted evenly positioned along arm portion of the body 101 each via a motorized slider 110, a pair of curved fins 111 including curved plate 112 attached with a motorized hinge joint 113, a pair of extendable L-brackets 114 positioned on the body’s collar portion, the brackets 114 are equipped with motorized bristles 115 , straps 116 integrated with the roller attach front portion of the body 101, and a user interface which is installed in a computing unit 117 linked with the microcontroller wirelessly by means of a communication module.

[0025] The system disclosed herein comprises of a wearable body 101 configured for donning over a user’s upper body like a vest or tight-fitting jacket, ensuring ease of movement during swimming activities. The body 101 is made from lightweight, water-resistant, and stretchable material to provide flexibility and durability. The body 101 securely houses embedded sensors and electronic components while maintaining a snug fit, allowing for uninterrupted monitoring and real-time feedback during swim sessions.

[0026] Once the body 101 is accommodated by the user, a push button is pressed by the user to activate the system for associated processes of the system. The push button when pressed by the user, opens up an electrical circuit and allows currents to flow for powering an associated microcontroller of the system for operating of all the linked components for performing their respective functions upon actuation.

[0027] The microcontroller activates an integrated ultrasonic sensor synced with an artificial intelligence-based imaging unit 103 installed on the body 101 for capturing and processing a sequence of images of the user’s torso portion to detect user’s torso portion dimensions. The imaging unit 103 incorporates a processor that is encrypted with an artificial intelligence protocol. The artificial intelligence protocol operates by following a set of predefined instructions to process data and perform tasks autonomously. Initially, data is collected and input into a database, which then employs protocol to analyze and interpret the captured images. The processor of the imaging unit 103 via the artificial intelligence protocol processes the captured images and sent the signal to the microcontroller.

[0028] The ultrasonic sensor disclosed herein, consists of an emitter and a receiver that acts as a transducer. The emitter emits ultrasonic sound waves towards torso portion. Then, the radiation strike to the user’s torso and reflect back which are captured by the receiver. The signal from the ultrasonic sensor is sent to the microcontroller. The microcontroller processes the combined signal of the ultrasonic sensor and the imaging unit 103 such that analyzes the dimension torso.

[0029] The body 101 is equipped with a pair of motorized rollers 102 are integrated with straps 116, installed on a front portion of the body 101, activated by the microcontroller to secure the body 101 over the user’s torso portion. The motorized rollers 102 integrated into the front portion of the body 101 work by using motors to control the tension and positioning of straps 116 that secure the wearable system over the user's torso. Each roller is equipped with a motorized mechanism that allows the rollers 102 to rotate in a controlled manner. These rollers 102 are connected to the straps 116, which is adjusted to fit the user’s body securely. When the user wears the system, the microcontroller activates the motorized rollers 102 to wind or unwind the straps 116, tightening or loosening them as needed.

[0030] The rollers 102 are integrated with flex sensors to provide feedback, based on which rollers 102 adjust tightness of the body 101 autonomously. As the rollers 102 adjust the straps 116, the flex sensors detect the amount of bending or stretching occurring in the strap material. When the straps 116 are too tight or too loose, the flex sensors register a significant change in resistance based on the degree of flexing. This information is sent to the microcontroller, which processes and determines whether the straps 116 need to be tightened or loosened.

[0031] The user provides the voice command via a microphone 104 to adjust the strap 116, ensuring optimal comfort and fit. The microphone 104 consists of a diaphragm, typically made of a thin, flexible material such as metal or plastic. When sound waves reach the microphone 104, leads to providing a vibrating movement to the diaphragm. These vibrations are directly proportional to the variations in air pressure caused by the sound waves. The diaphragm is coupled to a coil of wire, as the diaphragm vibrates, the coil moves within a magnetic field, inducing an electric current in the wire. This current is proportional to the amplitude and frequency of the sound waves. The electrical signal generated by the diaphragm-coil is transmitted to the microcontroller associated with the system.

[0032] Simultaneously, the user accesses a user interface which is inbuilt in a computing unit 117 linked with the microcontroller wirelessly by means of a communication module. The user interface enables the user to provide input regarding medical and physiological details of the user. The communication module includes, but not limited to Wi-Fi (Wireless Fidelity) module, Bluetooth module, GSM (Global System for Mobile Communication) module.

[0033] The communication module used in the present invention is preferably Wi-Fi module that contains transmitters and receivers that use radio frequency signals to transmit data wirelessly to the microcontroller. The wireless module typically includes components such as antennas, amplifiers, and processors to facilitate communication and further connected to networks such as Wi-Fi, module allowing system to exchange information to facilitate operations of the system.

[0034] The microcontroller linked with a processing unit of the computing unit 117 processes the details to store into a linked database that is configured to for creating and updating a personalized user health profile. The motion sensor typically uses accelerometer and gyroscope to detect changes in position, speed, and orientation of the user's body. These sensors are capable of capturing even the slightest movements, such as the flexing of muscles or shifts in posture.

[0035] The imaging unit 103, provides a visual feed of the user’s body, focusing on key areas such as the arms and legs during swimming. The microcontroller syncs the data from both the motion sensor and the imaging unit 103, processing it to analyze the user's movement patterns. By combining the motion data with visual feedback, the system can assess the swimmer’s form, technique, and coordination in real-time.

[0036] The body 101 is mounted with a hemispherical hydrophobic member 107 around the collar designed to be pulled over the swimmer’s head for shielding the user’s hair from water ingress during swimming. The member 107 contains an inflatable lining on inner side of the member 107 that is actuated by the microcontroller to inflate through the command from the microcontroller to ensure a tight and protective fit.

[0037] An air compressor, activated by the microcontroller inflates inflatable lining by drawing in atmospheric air and compressing it with a piston compressor. In a piston compressor, air is first drawn into a chamber when the piston moves down. Then, when the piston moves back up, it squeezes the air, making it more pressurized. This high-pressure air is then pushed out through a valve and sent into the inflatable lining to fill it up.

[0038] The member 107 is embedded an EEG (electroencephalographic) sensor for monitoring real-time stress levels that are logged into the user’s profile for longitudinal tracking. ECG sensor detects blood flow changes in the pet's neck area through electrical signals. ECG sensors measure electrical signals produced by the heart's activity through electrodes placed on the collar. The collected data is processed and transmitted to the microcontroller to monitor the user’s heart rate in real time. The EEG sensor is configured to communicate the monitored stress levels to the user interface for tracking long-term stress variations correlated with swimming sessions.

[0039] In case the user desires to practice swimming, the user provides provides input the via the microphone 104 installed on the body 101 regarding a user-desired swimming stroke to be practiced. The microphone 104 works in the same manner as described earlier. The microcontroller processes the command and activate a holographic projection unit 105 installed on the body 101 for projecting three-dimensional visual guides illustrating stepwise execution of the desired stroke.

[0040] The holographic projection unit 105 works by using advanced visual display module to project three-dimensional images or animations into the air around the user. When the swimmer inputs a desired stroke via the microphone 104, the microcontroller processes the voice command and activates the holographic unit. The unit uses a combination of light sources, such as lasers or LED projectors, directed through special lenses or holographic surfaces to create floating, 3D visual guides.

[0041] These guides illustrate the stepwise execution of the swimming stroke in real-time, helping the user visualize the proper movements. The holographic images are designed to show key aspects of the stroke, such as arm positions, hand angles, and timing, making it easier for the user to follow and replicate the technique.

[0042] Simultaneously, the microcontroller activates a motion sensor is integrated in the body 101 and synced with the imaging unit 103 for detecting the user’s movement in real-time. The motion sensor integrated into the swimming assistive system works by detecting changes in movement, position, and orientation of the user's body. The sensor includes an array of sensors such as accelerometers and gyroscopes.

[0043] The accelerometer measures acceleration forces in three dimensions (X, Y, and Z axes) to detect changes in the swimmer's position or speed. The gyroscope measures the rotation or angular velocity of the body 101, which helps track the user’s movements, such as arm strokes or leg kicks. These sensors continuously monitor the user’s motion, and collected data is sent to the microcontroller.

[0044] In case any deviation is detected, the microcontroller triggers a speaker 106 mounted on the body 101 to issue corrective verbal guidance. The speaker 106 works by converting the electrical signal into the audio signal. The speaker 106 consists of a cone known as a diaphragm attached to a coil-shaped wire placed between two magnets. When the electric signal is passed through the voice coil, generating a varying magnetic field that interacts with the magnet causing the diaphragm to move back and forth. This movement pushes and pulls air creating sound waves just like the electrical signal received and used to provide guidance.

[0045] The shoulder and collar portions of the body 101 are integrated a dual cardan joint 108 for inducing controlled movement to the body 101 relative to the user’s arms. The dual cardan joint 108 consists of two such joints 108 arranged in a way that they work together to enable controlled, multi-directional movement between the wearable body 101 (on the user’s torso) and the user’s arms.

[0046] This setup ensures that the arm movements are fluid and responsive, while also providing resistive force during swimming strokes. The dual cardan joint’s key feature is that it provides flexibility while also limiting excessive or awkward movement, offering stability and control during exercise. This helps in delivering a counteractive resistive force to the user’s upper limbs during arm movement in water, facilitating a resistance-based strength conditioning of arms.

[0047] The microcontroller is linked with a force sensor and a strain to provide real-time feedback. The force sensor measures the amount of force applied by the user, typically by detecting the pressure or weight exerted on a surface. In the context of the swimming assistive system, the force sensor is embedded in key areas (like the arm or body) to detect how much force the user is applying during swimming strokes or resistance training, that works by converting mechanical force into an electrical signal, which can then be analyzed by the microcontroller.

[0048] The strain sensor measures the deformation (strain) that occurs when a material is subjected to force. The sensor is made of a material that changes its electrical resistance when stretched or compressed The user moves or exerts force, the strain sensor detects these changes and sends the data to the microcontroller. This allows the system to track the swimmer’s movements, such as arm stroke power, and make adjustments accordingly.

[0049] Based on the feedback, the resistive force is dynamically adjusted for optimizing user exertion threshold while ensuring safe training limits. If the microcontroller detects that the user is pushing beyond their safe exertion limit, either through excessive force or improper movement, the microcontroller uses this data to adjust the resistive force in real time. This means that will either reduce the resistance to prevent overexertion or increase it slightly to encourage greater effort, ensuring that the user trains within a safe and optimal range.

[0050] The swimming strokes are further optimized for user to learn new techniques through a plurality of flaps 109 mounted evenly positioned along arm portion of the body 101. The flaps 109 are positioned via a motorized slider 110, that are selectively activated by the microcontroller to provide movement to the flaps 109 to get opened/closed with the user’s arm strokes. The motorized slider 110 in the swimming assistive system functions as a linear actuator that controls the movement of flaps 109 positioned along the arm portion of the wearable body 101. Each flap is mounted on a slider 110 mechanism that allows it to move along a guided track. The microcontroller receives real-time data from motion sensors and the imaging unit 103 to analyze the swimmer's arm movements. Based on the detected stroke pattern, the microcontroller selectively activates the motorized slider 110, which move the flaps 109 to open or close in sync with the user’s strokes. The slider 110 operates using a small electric motor that drives a gear, allowing precise and responsive linear motion.

[0051] In case of a suboptimal arm stroke execution is detected via the imaging unit 103, the microcontroller actuates a motorized hinge joint 113 to move an attached curved plate 112, the system also includes a pair of curved fins 111 in converging/diverging movement for improving foot movement and coordination with the arm strokes, thus facilitating in enhanced and effective swimming practice. The hinge typically operates through an electric motor connected to a gear, which moves the fins 111 inward (converging) or outward (diverging) in a synchronized manner with the swimmer's arm strokes. This controlled motion ensures that the fins 111 provide optimal resistance and assist in improving foot coordination, making it easier for the swimmer to align their leg movements with their arm strokes. The hinge’s precise control helps in fine-tuning swimming technique and boosting overall efficiency in the water.

[0052] The motion sensors track the user’s arm and foot coordination, and based on real-time feedback, the motorized fins 111 are activated to correct improper foot movements during swimming to improve swimming efficiency. These sensors detect the precise position, speed, and coordination of both limbs, allowing the system to monitor the alignment of the swimmer's strokes. If any discrepancy or misalignment between the arm and foot movements is detected, the microcontroller processes this data and sends a signal to activate the motorized fins 111.

[0053] The fins 111, attached to motorized hinge joint 113, adjust their position accordingly to provide resistance or assistance in the correct direction. If the foot movements are out of sync with the arm strokes, the motorized fins 111 will either converge or diverge to guide the feet into the proper position, helping the swimmer achieve better coordination.

[0054] In addition, the system includes a feature to detect pain in user’s ear while swimming, via facial expressions of the user detected by the imaging unit 103. If the pain is detected, a pair of extendable L- brackets 114 positioned on the body’s collar portion, and equipped with motorized bristles 115, activated by the microcontroller to provide massage to the user’s ears. These L-shaped brackets 114 are extendable and positioned to align with the user’s ears. The system’s artificial intelligence based imaging unit 103 continuously analyzes the user's facial expressions to detect signs of discomfort or pain, particularly around the ears, such as grimacing or muscle tension.

[0055] When such indicators are identified, the microcontroller activates the L- brackets 114, causing them to extend gently toward the user’s ears. Simultaneously, small motorized bristles 115 embedded on the inner side of the brackets 114 begin to oscillate or rotate to perform a soft massaging action around the ear area. The motorized bristles 115 are small, flexible projections are made of soft silicone or rubber mounted on a rotating or vibrating platform powered by an electric motor. When the microcontroller activates the motor, it drives the platform to either rotate in circular motions or vibrate at controlled speeds. This causes the bristles 115 to move in rhythmic patterns against the skin, producing a massaging effect.

[0056] Further, the user interface is integrated with a communication module that enables connectivity with an authorized doctor and sends real-time updates for taking care of the emotional well-being of the user to the computing unit 117, and receiving notifications in case of an emergency. During a swimming session, the system continuously monitors the user's emotional and physiological status using the embedded EEG sensor and imaging unit 103. The data is processed by the microcontroller and transmitted in real time to the linked computing unit 117. This includes indicators like stress levels, abnormal patterns, or signs of emotional distress. If the microcontroller identifies readings outside of safe thresholds, it automatically sends alerts or status updates to the doctor’s interface.

[0057] Furthermore, the imaging unit 103 detects improper limb coordination, and the arm and foot portions of the body are embedded with a plurality of vibration modules to deliver localized haptic feedback to the user. The vibration unit used in the swimming assistive system functions as a haptic feedback mechanism that provides real-time physical cues to the user. Each unit consists of a compact vibration motor, such as an eccentric rotating mass (ERM) embedded within the arm and foot sections of the body. When the artificial intelligence powered imaging unit 103 detects improper limb coordination or stroke inefficiencies, the microcontroller sends an electrical signal to the corresponding vibration motor. This signal activates the motor, causing it to generate a controlled vibration localized to the affected limb. The vibration serves as an immediate and non-verbal alert, prompting the user to correct their movement.

[0058] The microcontroller is also wirelessly synchronized with a database that is configured to store multi-session performance metrics, physiological stress indicators, and corrective stroke patterns for analysis by healthcare professionals and swimming coaches. During use, the microcontroller collects real-time data from various embedded sensors, including motion sensors, EEG sensors, force and strain sensors, and imaging units 103.

[0059] This data includes performance metrics, stress levels, limb coordination patterns, and instances of corrective feedback. Upon completion of each session, the system uploads this data via a secure wireless connection (such as Wi-Fi or Bluetooth) to a cloud-based or locally hosted database. The stored data is organized into session-wise logs that track the user's progress over time.

[0060] Moreover, a battery is installed within the system which is connected to the microcontroller that supplies current to all the electrically powered components that needs an amount of electric power to perform their functions and operation in an efficient manner. The battery utilized here, is generally a dry battery which is made up of Lithium-ion material that gives the system a long-lasting as well as an efficient DC (Direct Current) current which helps every component to function properly in an efficient manner. As the system is battery operated and do not need any electrical voltage for functioning. Hence the presence of battery leads to the portability of the system i.e., user is able to place as well as moves the system from one place to another as per the requirements.

[0061] The present invention works best in the following manner, where the body 101 is made of lightweight, water-resistant material, to enhance swimming performance and safety. Once the system is activated, the system’s microcontroller powers various components, including an ultrasonic sensor and artificial intelligence powered imaging unit 103, to analyze the user’s torso dimensions. The strap guided by flex sensors and voice commands through a microphone 104, ensures secure and comfortable fit. The system tracks physical and emotional parameters using motion sensors, EEG and ECG sensors, and the user interface connected via wireless communication modules. Real-time feedback is delivered through holographic projections, haptic vibration unit, or speaker 106 to guide stroke correction and improve technique. Additional components include inflatable hydrophobic headgear, resistance-adjusting flaps 109 and fins 111, and ear-massaging motorized bristles 115 triggered by facial expression analysis. The dual cardan joint 108 allows controlled resistance for arm conditioning, while force and strain sensors monitor exertion levels to prevent overtraining. The system communicates with healthcare professionals, stores multi-session data on the cloud or local database, and provides personalized feedback to support technical skill development, injury prevention, and mental wellness, making comprehensive smart training solution for swimmers.

[0062] Although the field of the invention has been described herein with limited reference to specific embodiments, this description is not meant to be construed in a limiting sense. Various modifications of the disclosed embodiments, as well as alternate embodiments of the invention, will become apparent to persons skilled in the art upon reference to the description of the invention. , Claims:1) An artificial intelligence-integrated swimming assistive system for real-time learning, stress monitoring, and emotional wellness, comprising:

i) a wearable body 101 configured for donning over a user’s upper body, wherein a pair of motorized rollers 102 are integrated with straps 116, installed on a front portion of said body 101, said rollers 102 are dynamically adjusted by an inbuilt microcontroller, to secure said body 101 over said user’s torso portion, dimensions of which are detected by an integrated ultrasonic sensor synced with an artificial intelligence-based imaging unit 103 installed on said body 101 and paired with a processor by capturing and processing a sequence of images of said user’s torso portion;
ii) a user interface inbuilt in a computing unit 117 wirelessly linked with said body 101 for enabling a user to provide input commands regarding medical and physiological details of said user, wherein said microcontroller is operably linked with a processing unit of said computing unit 117 for processing said details to store into a linked database that is configured for creating and updating a personalized user health profile;
iii) a hemispherical hydrophobic member 107 integrally mounted at collar portion of said body 101, adapted to be worn by said user on said user’s head for shielding said user’s hair from water ingress during swimming, wherein an inflatable lining is attached on inner side of said member 107 that is actuated by said microcontroller to inflate for acquiring secure fitting over said user’s head, in view of allowing a EEG (electroencephalographic) sensor integrated within said member 107 for monitoring real-time stress levels that are logged into said user’s profile for longitudinal tracking;
iv) a microphone 104 installed on said body 101 for enabling said user to provide input voice based commands regarding a user-desired swimming stroke to be practiced, wherein said microcontroller processes said commands to activate a holographic projection unit 105 installed on said body 101 for projecting three-dimensional visual guides illustrating stepwise execution of said desired stroke, herein a motion sensor is integrated in said body 101 and synced with said imaging unit 103 for detecting said user’s movement in real-time, and in case any deviation is detected, said microcontroller triggers a speaker 106 mounted on said body 101 to issue corrective verbal guidance;
v) a dual cardan joint 108 integrated within shoulder and collar portions of said body 101 for inducing controlled movement to said body 101 relative to said user’s arms, in view of delivering a counteractive resistive force to said user’s upper limbs during arm movement in water, facilitating a resistance-based strength conditioning of arms, wherein said resistive force is dynamically adjusted based on real-time feedback from a force sensor and a strain sensor, linked to said microcontroller, in view of optimizing user exertion threshold while ensuring safe training limits;
vi) a plurality of flaps 109 mounted evenly positioned along arm portion of said body 101, each via a motorized slider 110, that are selectively activated by said microcontroller to provide movement to said flaps 109 to get opened/closed with said user’s arm strokes, for optimizing said strokes across various swimming techniques; and
vii) a processing unit of a pair of curved fins 111 including curved plate 112 attached with a motorized hinge joint 113, wherein upon detection of suboptimal arm stroke execution, said microcontroller communicates with said processing unit to actuate said hinge joint 113 that is activated by said microcontroller to provide controlled converging/diverging movement to said fins 111 for improving foot movement and coordination with said arm strokes, thus facilitating in enhanced and effective swimming practice.

2) The system as claimed in claim 1, wherein said motorized rollers 102 are configured to adjust tightness of said body 101 autonomously based on real-time data from flex sensors and user voice commands captured by said microphone 104, ensuring optimal comfort and fit.

3) The system as claimed in claim 1, wherein a pair of extendable L- brackets 114 are positioned on said body’s collar portion, said brackets 114 are equipped with motorized bristles 115 that are activated by said microcontroller to provide massage to said user’s ears if pain is detected while swimming, via facial expressions of said user detected by said imaging unit 103.

4) The system as claimed in claim 1, wherein said user interface is integrated with a communication module that enables connectivity with an authorized doctor, sending real-time updates regarding said user’s stress levels and emotional well-being to a wirelessly linked computing unit 117, and receiving notifications in case of an emergency.

5) The system as claimed in claim 1, wherein said motorized fins 111 are actuates to correct improper foot movements during swimming, based on data from said motion sensors that track said user’s arm and foot coordination, and are adjustable based on real-time feedback to improve swimming efficiency.

6) The system as claimed in claim 1, wherein said EEG sensor is configured to communicate said monitored stress levels to said user interface for tracking long-term stress variations correlated with swimming sessions.

7) The system as claimed in claim 1, wherein said microcontroller activates a plurality of vibration modules embedded within said arm and foot portions of said body 101 to deliver localized haptic feedback to said user upon detection of improper limb coordination.

8) The system as claimed in claim 1, wherein said microcontroller is wirelessly synchronized with said database that is configured to store multi-session performance metrics, physiological stress indicators, and corrective stroke patterns for analysis by healthcare professionals and swimming coaches.