Description:FIELD OF THE INVENTION

[0001] The present invention relates to a workout support and safety device designed for enhancing workout safety and effectiveness by providing autonomous movement, real-time exercise monitoring, personalized assistance, and injury prevention within an exercise facility, while managing user data and offering suitable workout guidance.

BACKGROUND OF THE INVENTION

[0002] During workouts, individuals face challenges similar to those addressed by the invention for newborns. Maintaining a safe and controlled environment is crucial to preventing injuries, ensuring proper posture, and avoiding strain. Excessive noise can disrupt focus and performance, much like how it affects infant sleep. Poor posture and incorrect form can lead to injuries, while inadequate warm-up or stretching increases the risk of muscle strain. Using improper equipment or unsuitable footwear can cause joint stress and discomfort. Dehydration and overexertion may lead to fatigue or dizziness, affecting performance. Lack of supervision or guidance, especially for beginners, raises the risk of accidents. Environmental factors, such as slippery surfaces or inadequate lighting, can also pose safety concerns. Lastly, failing to listen to one’s body and pushing beyond limits may result in long-term health complications.

[0003] Traditionally, fitness devices such as static weightlifting racks, resistance bands, and wearable fitness trackers have been used to assist users in exercise facilities. These tools provide basic support or data tracking but lack autonomous movement, real-time form assessment, or adaptive physical assistance. Wearables monitor metrics like heart rate but cannot stabilize equipment or prevent injuries from improper form. Fixed gym equipment offers no personalized guidance or emergency response. These limitations result in inadequate support for dynamic workout needs, leaving users vulnerable to injuries and unable to access tailored exercise plans, necessitating an advanced, integrated solution.

[0004] US4757998A discloses a safety device for use in bench pressing includes at least one bar overlying a bench in a generally longitudinal direction. The bar, or preferably pair of bars, is located near the center line of the bench and is preferably pivotally moveable downward to an operable position in which it overlies the bench. Hooks for retaining a weight upon supporting uprights while the device is pivoted up from its operable position and locks for locking the device in the weight-retaining position may also be provided.

[0005] US7044896B2 discloses an exercise device having many advantageous features is described, including the ability to provide a user selected resistance from nearly zero resistance to the user's full body weight, the ability to easily adjust between exercises and between users, and the ability to balance the device between reconfigurations to provide for ease-of-use. The device includes an inelastic adjustable length member with two arms and a grip at both ends, and a centrally located anchor that provides for a distribution of the length between the arms. In one embodiment, the exercise device is compact and can be removably attached to a door frame. When grabbing each of the grips and uniformly pulling away from the anchor, the arms of the device center on the anchor.

[0006] Conventionally, many devices have been developed to facilitate support and safety during workout, however devices mentioned in prior art have limitations pertaining to the ability to autonomously navigating facilities, providing real-time physical support, or dynamically stabilizing equipment. Additionally, the existing devices fail to integrate user-specific workout plans or respond to emergencies, leaving gaps in safety, personalization.

[0007] In order to overcome the aforementioned drawbacks, there exists a need in the art to develop a device that is capable of navigating independently, adjusting physical assistance in real time, or stabilizing equipment during exercises. Additionally, the device is capable of support dynamic integration of user health data or customized workout plans, and delivering personalized, data-driven guidance while prioritizing user safety and workout efficiency.

OBJECTS OF THE INVENTION

[0008] The principal object of the present invention is to overcome the disadvantages of the prior art.

[0009] An object of the present invention is to develop a device that is capable of moving independently within an exercise facility to position itself effectively near a user, enabling real-time monitoring and assistance during workouts.

[0010] Another object of the present invention is to develop a device that is capable of assisting users by automatically adjusting physical support during exercises based on real-time assessment of their form and difficulty, improving exercise effectiveness and safety.

[0011] Another object of the present invention is to develop a device that is capable of enhancing workout safety by automatically stabilizing or securing exercise equipment, preventing injuries from unstable or falling equipment during workouts.

[0012] Another object of the present invention is to develop a device that is capable of offering personalized workout guidance by allowing users and trainers to upload, access, and manage customized exercise plans, ensuring customized support for individual fitness goals.

[0013] Another object of the present invention is to develop a device that is capable of monitoring and storing user health and workout data, enabling dynamic adjustments to exercise plans based on real-time progress, goals, and health conditions.

[0014] Yet another object of the present invention is to develop a device that is capable of detecting and responding to potential injuries or emergencies during workouts by analyzing user movements and health indicators, providing timely notifications to authorized individuals.

[0015] 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

[0016] The present invention relates to a workout support and safety device developed to autonomously navigate an exercise facility to monitor and assist users during workouts, providing real-time physical support, stabilizing equipment, and delivering personalized exercise guidance while enhancing safety and effectiveness.

[0017] According to an embodiment of the present invention, a workout support and safety device comprises of a body installed with an imaging unit, configured to navigate autonomously within an exercise facility, a plurality of motorized Tri-Star wheels is arranged underneath the body for omnidirectional movement of the body within the exercise facility and effective positioning of the body relative to a user performing exercises, a motorized roller mounted on the body carrying a stretchable support band for unrolling the band to provide physical assistance during exercises, a pair of telescopic L-shaped rods mounted on vertical sliders provided with the body, the rods include integrated electromagnetic springs to absorb weight and provide support by actuating beneath the user’s elbows during weightlifting to prevent accidental dropping of weights and enhance workout safety, a foldable horizontal plate mounted at an outer periphery of the body via a motorized ball and socket joint, the plate is automatically folded or unfolded, the plate actuating to interpose between the user and the equipment to prevent injury, a pair of L-shaped telescopic bars mounted on the body via a motorized spherical joint, each bar comprising a three-point gripper at a front end, the bars automatically actuate to assist the user in lifting weights or securing exercise equipment safely and effectively during workout sessions.

[0018] According to another embodiment of the present invention, the device further includes a horizontal pole mounted on the body actuated via a motorized pusher, a cushioned panel is arranged in front of the rod, and the rod automatically pushes against a user’s legs during leg raise exercises to provide adjustable resistance and assist in workout intensity enhancement, an user-interface is inbuilt in a computing unit accessed by users and trainers to upload and access customized workout plans, a database in integrated with the microcontroller for storing and continuously updating user data, enabling dynamic adjustment of exercise protocols and real-time monitoring, a thermal camera mounted on the body and paired with the imaging unit, configured to capture thermal images of the user's body to detect inflammation, sensors including accelerometers and gyroscopes integrated with the body for detecting impact forces and falls during workouts, and a battery is associated with the device for supplying power to electrical and electronically operated components associated with the device.

[0019] 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

[0020] 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 an isometric view of a workout support and safety device.

DETAILED DESCRIPTION OF THE INVENTION

[0021] 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.

[0022] 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.

[0023] 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.

[0024] The present invention relates to a workout support and safety device developed to independently moving within a fitness facility to observe and facilitate users during exercise, offering real-time physical assistance, securing equipment, and providing customized workout guidance to enhance safety and efficiency.

[0025] Referring to Figure 1, an isometric view of a workout support and safety device is illustrated, comprising a body 101 installed with an imaging unit 102, a plurality of motorized Tri-Star wheels 103 arranged underneath the body 101, a motorized roller 104 mounted on the body 101 carrying a stretchable support band 105, a pair of telescopic L-shaped rods 106 mounted on vertical sliders 107 provided with the body 101, the rods 106 include integrated electromagnetic springs 108, a foldable horizontal plate 109 mounted at an outer periphery of the body 101 via a motorized ball and socket joint 110, a pair of L-shaped telescopic bars 111 mounted on the body 101 via a spherical joint 112, each bar comprising a three-point gripper 113 at a front end, a horizontal pole 114 mounted on the body 101 actuated via a motorized pusher 115, a cushioned panel 116 arranged in front of the pole 114, and a thermal camera 117 mounted on the body 101.

[0026] The disclosed device herein comprising of a body 101 installed with an imaging unit 102 designed to withstand operational stresses while maintaining stability during movement within an exercise facility. The material composition of the body 101 is selected for durability and lightweight efficiency, allowing unobstructed movement. The imaging unit 102 herein comprises of an image capturing arrangement including a set of lenses that captures multiple images of the user performing exercises, and the captured images are stored within memory of the imaging unit 102 in form of an optical data.

[0027] The imaging unit 102 also comprises of a processor that is fed with artificial intelligence protocols, such that the processor processes the optical data and extracts the required data from the captured images. The extracted data is further converted into digital pulses and bits and are further transmitted to an inbuilt microcontroller. The microcontroller processes the received data and motion detection and user monitoring. A plurality of motorized Tri-Star wheels 103 is installed underneath the body 101 for enabling omnidirectional movement of the body 101 within the exercise facility. Each wheel 103 consists of three rotating sub-wheels mounted on a central hub, allowing seamless traversal over uneven surfaces and obstacles.

[0028] The wheels 103 operate through independent motorized control, facilitating precise directional adjustments. The microcontroller employs stabilization to maintain balance during movement, ensuring smooth transitions between positions. The Tri-Star configuration enhances maneuverability, enabling swift repositioning relative to the user. The wheels' adaptive suspension unit mitigates impact forces, preserving structural integrity during continuous operation.

[0029] Upon detecting the user's exercise routine by the imaging unit, a motorized roller 104, installed on the body 101 carrying a stretchable support band 105, automatically unrolls the band 105 for providing physical assistance during exercises. The roller 104 is responsible for controlled deployment and retraction of the stretchable support band 105. The roller 104 operates through a motor that regulates rotational movement based on real-time feedback from the imaging unit 102.

[0030] The motorized roller 104 herein comprises a disc coupled with a motor via a shaft integrated within a hub, wherein upon receiving the command from the microcontroller by the motor, the motor starts to rotate in clockwise or anti-clockwise direction in order to provide movement to the disc via the shaft. The roller 104 thus rotates to fit the band 105 for adjusting resistance dynamically to match user requirements. The stretchable support band 105 functions as an adjustable resistance and assistance unit for users performing exercises.

[0031] The stretchable support band 105 mentioned herein is composed of high-elasticity material designed to provide controlled tension based on user movement and difficulty level. The dynamic elasticity of the band 105 adapts to varying force applications, ensuring optimal support without restricting natural motion. Embedded reinforcement fibers enhance durability while maintaining flexibility. The band’s tension modulation assembly prevents abrupt force changes, ensuring smooth assistance transitions. The surface texture of the band 105 minimizes slippage, maintaining secure engagement with the user during exercise execution.

[0032] Based on user movement during weightlifting, the microcontroller actuates a pair of telescopic L-shaped rods 106 installed on vertical sliders 107 provided with the body 101, that function as adjustable support structures to extend and retract to adjusts its length dynamically to provide optimal support beneath the user’s elbows. The rods 106 comprise of integrated electromagnetic springs 108 function as dynamic weight absorption and support unit. The telescopic rods 106 are linked to a pneumatic unit, including an air compressor, air cylinders, air valves and piston which works in collaboration to aid in extension and retraction of the rods 106.

[0033] The pneumatic unit is operated by the microcontroller, such that the microcontroller actuates valve to allow passage of compressed air from the compressor within the cylinder, the compressed air further develops pressure against the piston and results in pushing and extending the piston. The piston is connected with the rods 106 and due to applied pressure the rods 106 extends and similarly, the microcontroller retracts the telescopic rods 106 by closing the valve resulting in retraction of the piston. Thus, the microcontroller regulates the extension/retraction of the rods 106 in order to synchronize with the electromagnetic springs 108 to absorb weight impact, preventing abrupt force application.

[0034] The vertical sliders 107 herein facilitate controlled linear movement of the telescopic rods 106 along the body’s structure. Each slider incorporates precision-guided tracks that regulate vertical displacement, ensuring smooth and stable adjustments. The sliders 107 operate through an automated actuation unit that responds to real-time feedback from the microcontroller, optimizing positioning relative to the user’s elbows. Integrated friction-reduction assembly enhance movement efficiency, preventing mechanical resistance. The sliders 107’ adaptive locking unit secures the rods 106 at designated positions, maintaining consistent support throughout exercise execution.

[0035] The electromagnetic springs 108 herein function as dynamic weight absorption and support. Each spring integrates an electromagnetic coil that modulates resistance based on user movement and applied force. The adaptive force of the springs 108 distribution assembly prevents sudden impact forces, ensuring smooth assistance transitions. The springs mitigates excessive vibrations, preserving structural integrity during continuous operation. The precision-controlled response assembly of the springs 108 enhances workout safety by preventing accidental weight drops.

[0036] Based on real-time monitoring from the imaging unit 102, the microcontroller actuates a foldable horizontal plate 109 configured at an outer periphery of the body 101 by means of a motorized ball and socket joint 110, functions as an automated safety barrier. The plate 109 is designed to extend or retract dynamically to interpose between the user and unstable equipment, preventing injury. The plate 109 operates through an integrated motorized hinge that regulates folding and unfolding actions. The plate’s structural composition ensures durability while maintaining lightweight efficiency.

[0037] The motorized ball and socket joint 110 mentioned herein includes a motor powered by the microcontroller generating electrical current, a ball shaped element and a socket. The ball moves freely within the socket. The motor rotates the ball in various directions that is controlled by the microcontroller that further commands the motor to position the ball precisely. The microcontroller further actuates the motor to generate electrical current to rotate in the joint for providing movement to the plate 109 for to secure the plate 109 at designated angles, ensuring stability during deployment.

[0038] A pair of L-shaped telescopic bars 111, affixed to the main body 101 by means of a spherical joint 112, for weightlifting and equipment stabilization. Each bar comprising a three-point gripper 113 at a front end, to secure weights or workout equipment with enhanced stability. The bars 111 extend and retract telescopically in response to user input or preset actuation parameters, providing structural support and controlled motion during exercise. The L-shaped configuration of the bars 111 ensures optimal force distribution and ergonomic handling. Integration of automated actuation facilitates dynamic adjustment, preventing undue strain and optimizing workout efficiency.

[0039] The bars 111 operate through synchronized extension and retraction, leveraging mechanical precision and stability to enhance user safety and effectiveness while lifting weights. The L-shaped telescopic bars 111 mentioned herein works in the same manner as of the telescopic L-shaped rods 106 mentioned above. The spherical joint 112 allows multi-directional movement by providing a rotational pivot between the telescopic bars 111 and the main body 101 structure. This joint comprises a ball-and-socket configuration, facilitating angular adjustments and seamless articulation. The design of spherical joint 112 ensures controlled fluid motion across multiple planes, optimizing ergonomic adaptability during exercise. The spherical joint 112 integrates friction-regulated movement, balancing flexibility with positional stability.

[0040] The three-point gripper 113 herein operates through three independent gripping elements, each actuated to engage objects through precision-controlled force application. The gripper's components adjust dynamically, conforming to varying object dimensions and surface textures. The gripper 113 is equipped with pressure-sensitive contact points, ensures secure engagement while mitigating slip risks. The working of the gripper 113 integrates synchronized force application, leveraging mechanical compliance to optimize grip security and operational efficiency, thereby ensuring user safety and minimizes unintended equipment displacement.

[0041] Upon successful detection of instability, a horizontal pole 114 installed on the body 101 actuated via a motorized pusher 115, functions as an adjustable resistance unit that engages dynamically during leg raise exercises. The pole 114 regulates force application based on user movement. The pole 114 synchronizes with the motorized pusher 115 to extend or retract, ensuring optimal resistance levels. The pole’s structural composition ensures durability while maintaining lightweight efficiency. The pole’s surface texture minimizes slippage, ensuring secure engagement with the user’s legs throughout workout sessions. Additionally, a cushioned panel 116 is arranged in front of the pole 114, that functions as a protective interface between the horizontal pole 114 and the user’s legs.

[0042] The motorized pusher 115 enables controlled linear movement of the horizontal pole 114. The pusher 115 operates through an integrated motor assembly that regulates displacement based on real-time feedback from the imaging unit 102. The pusher 115 adjust resistance dynamically, ensuring optimal workout intensity. The pusher secures the pole 114 at designated positions, maintaining consistent resistance levels. The reinforced structural design of the pusher 115 enhances operational reliability, minimizing wear and tear during prolonged usage.

[0043] The cushioned panel 116 herein is composed of high-density impact-absorbing material designed to provide controlled pressure distribution. The panel 116 integrates with the horizontal pole 114, adjusting its positioning dynamically to accommodate varying force applications. Embedded reinforcement layers enhance durability while maintaining flexibility. The panel’s surface texture minimizes friction, ensuring comfortable engagement during exercise execution. The adaptive compression of the panel 116 prevents excessive strain, maintaining consistent support throughout workout sessions. The panel’s precision-controlled response optimizes force absorption, ensuring safe and effective resistance application.

[0044] A user interface is installed within the computing unit accessed by the user and trainers that includes but is not limited to a smartphone and laptop for enabling the user to input commands to upload, modify, and access customized workout plans. The interface synchronizes with the computing unit to retrieve past exercise logs, current routines, and trainer-specified instructions. The interface supports real-time updates, ensuring dynamic adjustments based on user progress.

[0045] The computing unit is linked with the microcontroller via an integrated communication module that includes but is not limited to a GSM (Global System for Mobile Communication) module, a Wi-Fi module, or a Bluetooth module, which is capable of establishing a wireless network between the microcontroller and the computing unit. The computing unit used herein is capable of computing operations according to the user’s desire with the help of the user interface.

[0046] A database is integrated with the microcontroller to store and continuously update user-specific data, including weight targets, current weight, height, medical records detailing internal health conditions or injuries, and workout progress. This database enables real-time tracking and dynamic modifications to exercise protocols based on user needs. The database facilitates efficient monitoring, ensuring tailored guidance and adaptive workout adjustments to optimize performance and safety.

[0047] Additionally, a thermal camera 117 is installed on the body 101 and paired with the imaging unit 102, to capture heat signatures from the user’s body during exercise. The thermal camera 117 operates through an integrated infrared sensor array that detects temperature variations, generating thermal images for analysis. The thermal camera 117 captures the infrared radiation being emitted from user’s body by using an internal measuring unit that captures infrared radiation, called microbolometers.

[0048] The microbolometers capture the infrared radiations and convert them into an image that is analyzed using the artificial intelligence protocol to detect the inflammation. The information acquired by the thermal camera 117 is transmitted to the microcontroller. The microcontroller as per the image captured by the thermal camera 117 determines the inflammation or abnormal temperature fluctuations. Sensors integrated with the body 101, function as real-time monitoring units designed to detect impact forces and falls during workout sessions.

[0049] The sensors mentioned herein includes accelerometers and gyroscopes integrated with the body 101, operate through the microcontroller that continuously analyzes motion patterns and force variations. The sensors synchronize with the microcontroller to transmit collected data to the database for emergency notifications. Embedded calibration assembly ensure precise detection accuracy, minimizing false alerts. The sensors’ adaptive response optimizes sensitivity based on user activity levels. Their secure communication protocol facilitates seamless data transmission to authorized guardians or healthcare providers, ensuring timely intervention and enhanced workout safety.

[0050] The accelerometers herein function as motion detection units responsible for measuring linear acceleration and sudden movement changes. They operate through an integrated microelectromechanical system (MEMS) that detects variations in velocity and directional shifts. The accelerometers synchronize with the sensors to analyze impact forces, identifying abrupt deceleration indicative of falls. Embedded signal filtering unit enhance detection precision, reducing noise interference. The accelerometers’ adaptive threshold unit adjusts sensitivity dynamically based on user activity intensity. Their real-time data processing capability ensures immediate transmission to the database, enabling emergency alerts and workout adjustments for enhanced safety and injury prevention.

[0051] The gyroscopes synchronize with the accelerometers to assess user posture and movement integrity, identifying instability indicative of potential falls. The gyroscope herein consists of a spinning rotor that maintains its axis of rotation regardless of the orientation of the device. When the body 101 tilts or changes its inclination, the gyroscope's rotor tends to resist this change due to its angular momentum. The resistance to changes in orientation allows the gyroscope to detect the inclination level of the body 101. By measuring the forces applied as the rotor resists the changes in orientation, the gyroscope determines the inclination level of the body 101, which is then send to the microcontroller to detects rotational displacement and balance deviations.

[0052] Moreover, the battery is associated with the device for powering up electrical and electronically operated components associated with the device and supplying a voltage to the components. The battery used herein is preferably a Lithium-ion battery which is a rechargeable unit that demands power supply after getting drained. The battery stores the electric current derived from an external source in the form of chemical energy, which when required by the electronic component of the device, derives the required power from the battery for proper functioning of the device.

[0053] The present invention works best in following manner, where the microcontroller first activates the imaging unit 102, enabling autonomous navigation within the exercise facility and positioning the body 101 relative to the user. Upon detecting the user's exercise routine, the motorized roller unrolls the stretchable support band 105, offering assistance based on real-time monitoring of form and difficulty levels. As the user engages in weightlifting, the microcontroller actuates the telescopic rods 106, deploying electromagnetic springs 108 beneath the elbows to absorb weight and enhance stability, preventing accidental weight drops. Simultaneously, the imaging unit 102 monitors equipment positioning. If instability is detected, the foldable horizontal plate 109 unfolds and interposes between the user and the equipment to prevent injuries. As the workout progresses, the L-shaped telescopic bars 111 equipped with three-point gripper 113 engage to assist in lifting weights or securing exercise equipment effectively. For leg raise exercises, the microcontroller activates the horizontal pole 114, which pushes against the user's legs via the cushioned panel 116, providing adjustable resistance and enhancing workout intensity. Throughout the session, integrated sensors detect impact forces and falls, transmitting data to the database for emergency notifications. Additionally, the thermal camera 117 continuously scans for inflammation, enabling personalized exercise recommendations based on heat map analysis.

[0054] 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) A workout support and safety device, comprising:

i) a body 101 installed with an imaging unit 102, configured to navigate autonomously within an exercise facility, wherein a plurality of motorized Tri-Star wheels 103 is arranged underneath said body 101 for omnidirectional movement of the body 101 within the exercise facility and effective positioning of the body 101 relative to a user performing exercises;
ii) a motorized roller 104 mounted on said body 101 carrying a stretchable support band 105, wherein said roller 104 automatically unrolls said band 105 to provide physical assistance during exercises, based on monitoring from said imaging unit 102, assessing user form and difficulty in performing said exercises;
iii) a pair of telescopic L-shaped rods 106 mounted on vertical sliders 107 provided with the body 101, wherein the rods 106 include integrated electromagnetic springs 108 that are actuated by an inbuilt microcontroller to absorb weight and provide support by actuating beneath the user’s elbows during weightlifting to prevent accidental dropping of weights and enhance workout safety;
iv) a foldable horizontal plate 109 mounted at an outer periphery of said body 101 via a motorized ball and socket joint 110, configured to automatically fold or unfold based on real-time monitoring from said imaging unit 102 that detects unstable equipment positioning during exercises, wherein the plate 109 actuates to interpose between said user and the equipment to prevent injury;
v) a pair of L-shaped telescopic bars 111 mounted on said body 101 via a spherical joint 112, each bar 111 comprising a three-point gripper 113 at a front end, to assist the user in lifting weights or securing exercise equipment; and
vi) a horizontal pole 114 mounted on said body 101 actuated via a motorized pusher 115, wherein a cushioned panel 116 is arranged in front of said pole 114, and said pole 114 automatically pushes against a user’s legs during leg raise exercises to provide adjustable resistance and assist in workout intensity enhancement.

2) The device as claimed in claim 1, wherein a user-interface is inbuilt in a computing unit accessed by users and trainers to upload and access customized workout plans, including past exercise logs, current routines, and trainer-specified instructions, said plans are utilized by the microcontroller to coordinate workout sessions and provide tailored exercise guidance.

3) The device as claimed in claim 1, wherein a database in integrated with said microcontroller for storing and continuously updating user data including weight goals, current weight, height, medical reports including internal health issues or injuries, and workout progress, enabling dynamic adjustment of exercise protocols and real-time monitoring.

4) The device as claimed in claim 1, wherein a thermal camera 117 is mounted on said body 101 and paired with the imaging unit 102, configured to capture thermal images of the user's body to detect inflammation, and the microcontroller provides personalized exercise recommendations based on said heat map analysis.

5) The device as claimed in claim 1, wherein sensors including accelerometers and gyroscopes are integrated with said body 101 for detecting impact forces and falls during workouts, and collected data is transmitted to said database for emergency notifications and updates to authorized guardians or healthcare providers.

6) The device as claimed in claim 1, wherein a battery is associated with said device for supplying power to electrical and electronically operated components associated with said device.