Description:FIELD OF THE INVENTION

[0001] The present invention relates to a rhythmic performance training system designed to assist users in improving movement coordination, accuracy, rhythm, posture, and overall performance skills through structured practice, corrective guidance, interactive training, and enhanced learning support.

BACKGROUND OF THE INVENTION

[0002] Rhythmic performance, whether in music, dance, or sports, requires precision, coordination, and consistency, which traditional learning methods often fail to deliver effectively. Learners typically struggle with real-time error detection, posture correction, and maintaining synchronization in group settings. During rhythmic performance training, learners often face problems such as difficulty in maintaining consistent timing, coordination, and accuracy, as traditional methods rely heavily on subjective instructor feedback. Real-time error detection and correction are generally unavailable, leading to persistent mistakes in rhythm, posture, or movement technique. Group training further poses challenges in achieving synchronization and collective harmony without technological assistance. Additionally, existing tools like metronomes or audio cues provide only limited guidance, lacking comprehensive monitoring or corrective mechanisms. These issues result in slower progress, reduced engagement, risk of physical strain, and inconsistent learning outcomes, thereby limiting overall performance quality.

[0003] Traditionally, rhythmic performance training has been conducted through manual instruction under the supervision of teachers, coaches, or mentors. Learners typically follow verbal cues, demonstrations, or metronomic beats to develop timing and coordination. While such methods provide a foundation, they are heavily dependent on human observation and subjective feedback, often resulting in inconsistencies in learning outcomes. Group training sessions require significant synchronization and monitoring, which become challenging without technological assistance. Moreover, traditional methods rarely provide detailed feedback on errors such as timing deviations, movement irregularities, or posture misalignments, thereby limiting the ability of learners to achieve consistent and measurable improvement.

[0004] US20210128976A1 discloses a portable user device, method and computer program provide rhythmic athletic training assist by tracking an athletic proficiency level of a user. A respective sport control affordance for a plurality of sports are presented on a user interface of the portable user device. In response to a user selection of one sport control affordance associated with a selected sport, more than one drill control affordance for a type of athletic drill associated with the selected sport are presented on the user interface. In response to a user selection of a particular drill control affordance for a particular type of athletic drill, the type of athletic drill is associated with two or more available rhythmic speed settings. Based upon the tracked proficiency level of the user, one of the two or more rhythmic speed settings is selected. Video/audio guide is presented on the user interface at the selected rhythmic speed setting.

[0005] US10421002B2 discloses a system, equipment and process to guide a user in the experience of rhythmic exercise. Playback of an audio file/signal, such as a musical phrase, that has known rhythmic structure (e.g., beat pattern) is accompanied, by non-audio sensory cues such as a light signal or tactical signal (vibration) to mark rhythmic events in the audio playback (such as the beginning and end of playback and/or audio pulses (beats). In addition, equipment is provided to guide the user in performing a GDM (goal directed movement) sequence that is selected to be performed in synch with the rhythm of the audio signal. The user's motion is detected and compared to desired GDM in the selected sequence and also compared to the rhythm of the audio signal. Sensory cues are provided to guide the user in performing the GDM sequence rhythmically. The system may be implemented in cardio fitness equipment including treadmill, AMT, stationary exercise bike and elliptical type exercise equipment.

[0006] Conventionally, many systems have been developed to facilitate, however systems mentioned in prior arts have limitations pertaining to providing auditory or basic visual cues without delivering comprehensive feedback, and designed for individual use, lacking collaborative training support for group synchronization. Additionally, the existing systems often fail to monitor real-time body movements, detect posture deviations.

[0007] In order to overcome the aforementioned drawbacks, there exists a need in the art to develop a system that is capable of integrating real-time monitoring, corrective feedback, and interactive guidance. Additionally, the system is capable of ensuring accurate and effective rhythmic performance training for both individuals and groups, and enhancing user engagement through immersive interaction while prioritizing safety by reducing risks of imbalance or strain.

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 system that is capable of enabling users to learn and practice rhythmic performance in a structured and interactive manner.

[0010] Another object of the present invention is to develop a system that is capable of providing real-time monitoring and guidance to improve the accuracy, rhythm, and technique of users during training.

[0011] Another object of the present invention is to develop a system that is capable of delivering corrective feedback for movement errors, timing issues, or posture deviations to enhance performance quality.

[0012] Another object of the present invention is to develop a system that is capable of supporting both individual and group training sessions, allowing synchronized practice and interaction among multiple users.

[0013] Another object of the present invention is to develop a system that is capable of ensuring user safety during training by reducing risks of imbalance, missteps, or physical strain.

[0014] Yet another object of the present invention is to develop a system that is capable of improving user engagement and motivation by creating an immersive and responsive training environment.

[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 rhythmic performance training system developed for supporting users in developing coordination, precision, rhythm, posture, and performance skills by providing structured practice, corrective feedback, interactive learning, and guided improvement during training of rhythmic performance.

[0017] According to an aspect of the present invention, a rhythmic performance training system comprising of a base platform structured to be placed on a ground surface, configured to support one or more users performing various rhythmic performance routines, an AI (artificial intelligence)-powered imaging unit synced with a NIR (near infrared) sensor, mounted on the platform to detect user presence, facial expressions, body movement, and group formations on the platform, a foldable display unit placed on a pair of vertical extendable rods provided with the platform, configured to deploy via an integrated motorized scissor arrangement and display demo videos of selected rhythmic performance styles, a wearable training suit associated with system worn by the user, to assist a user in improving rhythmic performance form, technique, and performance during rhythmic performance training.

[0018] According to another aspect of the present invention, the present invention further includes a pair of wearable training shoes associated with the system, worn by the user to monitor footwork accuracy, rhythm, and posture during rhythmic performance training, a circular ring-based movement training arrangement integrated with the system and mounted on the platform, configured to assist a user during rhythmic performance training by providing a target for movement coordination and enabling performance correction during rhythmic performance steps, and a microcontroller configured to process data from sensors and user inputs, manage overall system operations, control output components, and deliver real-time feedback.

[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 rhythmic performance training system.

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 rhythmic performance training system developed for facilitating users in refining coordination, timing, posture, and movement accuracy, while enhancing overall performance skills through guided practice, interactive feedback, and structured learning support.

[0025] Referring to Figure 1, an isometric view of a rhythmic performance training system is illustrated, comprising of a base platform 101 structured to be placed on a ground surface, an AI (artificial intelligence)-powered imaging unit 102 mounted on the platform 101, a foldable display unit 103 placed on a pair of vertical extendable rods 104 provided with the platform 101, a motorized scissor arrangement 105 integrated with the platform 101, a wearable training suit 106 associated with system, the wearable training suit 106 comprises of a plurality of plates 107 interconnected by motorized pivot joints 108 aligned with the body's natural joint, a pair of wearable training shoes 109 associated with the system, a circular ring-based movement training arrangement integrated with the system and mounted on the platform 101, the circular ring-based movement training arrangement comprises of an extendable vertical bar 110 integrated with a circular ring 111, and a dual-axial horizontal slider 112, at least one holographic projection unit 113 mounted via a vertical extendable link 114.

[0026] The disclosed system herein comprises of a base platform 101 structurally configured to be securely positioned upon a ground surface. The platform 101 is dimensioned, and stabilized to accommodate the weight and movement of one or more users simultaneously. The platform 101 is adapted to sustain dynamic load variations generated during rhythmic performance routines, thereby ensuring structural integrity, user safety, and non-slip stability. The construction of the base platform 101 is directed towards enabling reliable support, durability, and functional adaptability during rhythmic performance training.

[0027] A user provides input commands via a user interface, inbuilt within a computing unit, configured as an interactive module enabling structured communication between the user and the rhythmic performance training system. The user interface is designed to facilitate reception of input commands from the user, including initiation of rhythmic performance practice sessions, selection of rhythmic performance styles, and provision of supplementary information relevant to personalized training.

[0028] The interface is further enable bidirectional interaction with the computing unit, thereby ensuring accurate data capture, responsiveness, and seamless operational execution in accordance with user-specific preferences and training requirements. The user interface operates by receiving user inputs through touchscreen, which are transmitted to the computing unit for processing. Upon receiving initiation commands, the interface triggers execution protocols to launch rhythmic performance practice.

[0029] The selection inputs related to performance styles are processed by the protocols to load corresponding training modules. User-provided data for personalization is stored in system memory and dynamically retrieved during practice sessions to adjust training parameters. The interface further displays real-time feedback and system prompts, thereby functioning as a continuous interactive control and monitoring medium. An AI (artificial intelligence)-powered imaging unit 102 installed on the platform 101 and synced with a NIR (near infrared) sensor for continuously capturing visual input from the platform 101 environment through integrated optical cameras.

[0030] The captured data is processed in real-time using machine learning protocols configured to recognize and classify user-specific attributes including facial expressions, body posture, gestures, and collective group formations. The camera applies computational protocols for motion tracking, pattern recognition, and predictive analysis to monitor rhythmic performance. The processed output is transmitted to the computing unit, enabling adaptive training feedback, synchronization of performance parameters, and automated adjustment of training protocols based on the detected user interactions and movement sequences.

[0031] The NIR sensor herein functions by emitting near-infrared light waves toward the platform 101 surface and detecting reflected signals from users present within its sensing field. The variations in the reflected light intensity are analyzed to determine user presence, proximity, and movement trajectories. The sensor further distinguishes between individual and multiple users by assessing the depth, contour, and heat-reflective properties of bodies in motion. This data is synchronized with the imaging unit 102 to enhance accuracy in detecting user positioning and formation.

[0032] The processed NIR signals facilitate low-light functionality, real-time tracking, and seamless integration with AI protocols for performance monitoring and feedback generation. Upon receiving a command signal through the computing unit, a foldable display unit 103 integrated with the base platform 101, deployed through controlled actuation and transitions to an operable state. The display unit 103 renders pre-stored or streamed rhythmic performance demonstrations. The display unit 103 placed on a pair of vertical extendable rods 104 and configured to deploy via an integrated motorized scissor arrangement 105. The folding and unfolding motion is facilitated by the scissor arrangement 105, ensuring stability during deployment and compact storage when retracted.

[0033] The display unit 103 thus enables visual guidance while conserving space during idle conditions. The pair of vertical extendable rods 104 herein designed to provide adjustable vertical support for the foldable display unit 103. The rods 104 operate in a telescopic manner, extending upward when actuated by the motorized scissor arrangement 105, and retracting downward when folded for storage. The extension enables positioning of the display unit 103 at variable user-preferred viewing heights, while the retraction facilitates compact stowing within the platform 101.

[0034] The rods 104 maintain axial alignment during extension and retraction, thereby ensuring structural stability and load support for the display unit 103. Upon activation through the computing unit, the integrated motor drives the scissor linkages in a synchronized manner to extend vertically, thereby raising the rods 104 and unfolding the display unit 103. The scissor arrangement 105 operates on a cross-lever principle; wherein motor torque translates into linear vertical displacement. The arrangement 105 provides smooth, controlled deployment and retraction of the display unit 103 while ensuring balanced movement and load distribution.

[0035] A wearable training suit 106 associated with system worn by the user, functions as an integrated performance-assistive component align with the user’s body to monitor, guide, and correct movements in real time during rhythmic performance training. The wearable training suit 106 includes of a plurality of plates 107 interconnected by motorized pivot joints 108, an integrated motion sensor embedded within the suit 106, and a plurality of vibrating units attached to the pivot joints 108. The suit 106 dynamically interprets movement data, simultaneously transmitting corrective impulses to enhance precision and rhythm during performance routines.

[0036] The suit 106 ensures consistent posture control, coordinated form adjustment, and accurate rhythmic execution in compliance with training protocols by integrating mechanical support and sensory guidance. The plurality of plates 107 within the wearable training suit 106 operates as segmented structural elements designed to conform to the user’s body while maintaining biomechanical alignment. Each plate 107 interfaces with adjoining plates 107 through the pivot joints 108, thereby replicating natural human articulation.

[0037] During rhythmic performance training, the plates 107 transmit mechanical adjustments and stabilize body movement trajectories to minimize deviation from prescribed form. The plates 107 provide distributed structural integrity to the suit 106, ensuring precise replication of movement while allowing sufficient flexibility for unrestricted practice. The coordinated operation facilitates accurate body positioning, enabling guided correction without obstructing range of motion or rhythmic fluidity.

[0038] The motorized pivot joints 108 herein function as articulated connectors between the plurality of plates 107, positioned strategically at the user’s anatomical joint locations. The pivot joints 108 actively replicate natural limb articulation by mechanically adjusting their angle in response to control signals from the microcontroller. During training, the pivot joints 108 synchronize user movements with motion patterns, ensuring accurate replication of rhythmic sequences. The pivot joints 108 deliver real-time mechanical corrections, thereby enabling the user to maintain precision, balance, and uniformity in rhythmic performance execution.

[0039] The integrated motion sensor mentioned above operates by continuously detecting positional data, angular displacement, velocity, and acceleration of body segments. Upon activation, the sensor captures real-time biomechanical parameters and transmits them to the microcontroller for analysis. The microcontroller compares detected motion against ideal performance models and identifies deviations in rhythm, form, or technique. Based on this analysis, corrective commands are issued to the pivot joints 108 and vibrating units.

[0040] The vibrating units attached to the pivot joints 108 operate as localized haptic feedback, and a plurality of suits are provided for accommodating simultaneous group rhythmic performance practice. Upon detection of improper alignment or deviation from motion sequences, the microcontroller transmits activation signals to the specific vibrating units. The vibrations are delivered directly at the user’s joint locations, creating haptic cues that guide corrective repositioning. By varying vibration intensity, frequency, and duration, the vibrating units provide differentiated feedback corresponding to the type and severity of movement error.

[0041] The haptic stimulation functions as a non-intrusive correction, enabling the user to adjust rhythm, posture, and form without interrupting the continuity of performance training. A pair of wearable training shoes 109 associated with the system, worn by the user and operates by continuously capturing biomechanical data during rhythmic performance routines and transmitting the same to the computing unit for real-time analysis.

[0042] The shoes 109 are embedded with sensors including a gyroscope sensor, and a plurality of integrated load sensors positioned at the toe, front, and heel regions of the shoes 109. The sensors configured to detect orientation, foot pressure, and posture parameters, and this data is processed to determine accuracy of footwork patterns. When deviations from pre-stored performance criteria are identified, corrective feedback is generated for the user through the interface.

[0043] The gyroscope sensor herein embedded within the wearable training shoes 109 functions by measuring angular velocity and orientation of the user’s foot across multiple axes during rhythmic performance steps. As the foot moves, the gyroscope sensor generates electrical signals proportional to its angular displacement and velocity, which are transmitted to the microcontroller of the system. These readings are compared against pre-determined rhythmic motion parameters to detect misalignments in foot orientation.

[0044] Upon detecting angular deviations, the microcontroller generates corrective guidance signals for real-time feedback, thereby enabling precise monitoring of foot positioning and enhancing the user’s overall accuracy, rhythm, and stability during performance training. The plurality of integrated load sensors mentioned herein operates by detecting dynamic pressure distribution exerted by the user’s foot during rhythmic performance execution. Each sensor generates analog signals corresponding to applied pressure levels, which are digitized and transmitted to the microcontroller.

[0045] The distribution data is analyzed to identify incorrect foot placement, imbalance, or irregular rhythm patterns. Based on this analysis, the microcontroller provides immediate corrective cues to the user. The coordinated operation of these load sensors ensures precise monitoring of step impact, weight balance, and rhythmic accuracy. A circular ring-based movement training arrangement operates as an interactive training apparatus mounted on the platform 101 and configured to provide real-time coordination targets during rhythmic performance training.

[0046] The circular ring-based movement training arrangement includes an extendable vertical bar 110 integrated with a circular ring 111, and a dual-axial horizontal slider 112. The circular ring 111 ensures the user performs prescribed movement sequences with enhanced precision. The arrangement works by dynamically guiding the user’s arm or body motion toward the ring 111 zone, thereby facilitating accurate trajectory and posture alignment. The arrangement registers deviations in user performance, enabling instant corrective feedback and adaptive repositioning for improved movement coordination and rhythm accuracy.

[0047] The extendable vertical bar 110 herein functions for structural adjustment of height calibration of the circular ring 111 in accordance with the user’s physical profile and selected rhythmic performance movements. The bar 110 operates through a telescopic extension, enabling incremental or automated adjustment of elevation. During training, the vertical bar 110 maintains the circular ring 111 at a stable and precise height, preventing displacement under repetitive user interaction. The extendable bar 110 ensures ergonomic adaptability, uniform resistance, and targeted motion training that accommodates diverse user groups and movement requirements by aligning the ring 111 height with specific movement trajectories.

[0048] The circular ring 111 functions as the principal engagement target for the user during rhythmic performance training, serving as a spatial reference point to guide limb or body movements. The ring 111 operates by maintaining a fixed, visible, and tactile structure that the user must align with, pass through, or coordinate movements around in synchronization with rhythmic cues. The dual-axial horizontal slider 112 is positioned at the base of the vertical bar 110 to reposition the circular ring 111 along two orthogonal axes across the platform 101 plane. The slider 112 works by enabling controlled automated displacement of the mounted ring 111, thereby aligning it with varied rhythmic performance routines requiring side-to-side or depth-oriented movement.

[0049] During training, the dual-axis slider 112 ensures the ring 111 is repositioned to correspond with sequences, allowing the user to adapt to dynamic motion patterns. The repositioning functionality enhances training versatility, enabling simulation of diverse movement trajectories while maintaining stability, accuracy, and synchronization with real-time performance monitoring. The microcontroller processes data from sensors and user inputs, manage overall system operations, control output components, and deliver real-time feedback. A holographic projection unit 113 is installed on a vertical extendable link 114, coupled with a universal joint to enable multidirectional rotation, thereby allowing the projection of either a holographic rhythmic performance partner or a virtual audience to facilitate user interaction and feedback.

[0050] The projection unit 113 configured to operate by receiving digital image data and processing the data into multi-dimensional frames, and emitting coherent light beams through an array of micro-optical projectors to form a three-dimensional holographic representation in free space. The projection unit 113 continuously refreshes projected frames in synchronization with audio outputs, thereby ensuring real-time interaction and lifelike presence. The projection unit 113 is operable to switch between holographic rhythmic performance partner and virtual audience modes based on user command inputs, thereby enabling dynamic visualization, interactive feedback, and simulated training environments for the user.

[0051] The vertical extendable link 114 herein is configured to vertically adjusts the positioning of the holographic projection unit 113 relative to the base platform 101. The link 114 operates by means of pneumatic cylinder that extend or retract the length of the link 114 in a controlled manner. The movement allows precise height calibration of the projection unit 113 in accordance with user posture, movement, or performance requirements. The universal joint is configured to mechanically couple the vertical extendable link 114 with the holographic projection unit 113, allowing multi-axis angular displacement and rotational freedom.

[0052] The universal joint operates by employing a cross-shaped pivot element connected to opposing yokes, wherein torque and motion transmitted from the extendable link 114 enable smooth orientation adjustments of the projection unit 113. This configuration permits the projection unit 113 to rotate and tilt across horizontal and vertical planes without mechanical obstruction. The universal joint thus facilitates dynamic alignment of holographic projections to varying user positions, enabling uninterrupted interaction, optimal visibility, and adaptive feedback during rhythmic performance training.

[0053] A plurality of pressure sensors is embedded within the surface of the platform 101 configured to detect and record the pressure exerted by the user’s foot during rhythmic tapping. The sensors generate corresponding electrical signals that are transmitted to the microcontroller, which analyzes the timing, intensity, and sequence of the foot taps. The plurality of pressure sensors operates by converting mechanical force, applied through user foot taps, into measurable electrical signals.

[0054] The sensors register variations in pressure intensity and duration, creating a signal pattern mapped against a predefined rhythmic template. The signals are continuously relayed to the microcontroller, which sequentially processes them to determine accuracy of timing and rhythm. Upon identification of a mismatch between the detected foot-tap sequence and the demo rhythm, the microcontroller pinpoints the specific deviation and replays the corresponding demonstration step for correction. This cycle repeats dynamically, ensuring precise synchronization between user performance and guided rhythmic training.

[0055] A plurality of inflatable cushion pads housed within rectangular tubes positioned around the periphery of the platform 101, the tubes being securely affixed to the structural frame thereof. Each inflatable cushion pad is connected to a pneumatic inflator governed by the microcontroller. Upon identification of imbalance or potential fall of the user, the microcontroller activates the pneumatic inflator to inflate the cushion pads, thereby providing a protective barrier to minimize impact forces and prevent injury during user training activities.

[0056] The inflatable cushion pads function through a controlled pneumatic actuation sequence. In normal conditions, the pads remain deflated and housed compactly within rectangular tubes. When balance sensors transmit fall-detection signals, the microcontroller instantaneously triggers solenoid valves to release compressed air from a storage canister into the cushion chambers via conduits. The rapid air influx expands the cushions outward from the tubes, forming a soft, energy-absorbing barrier around the user.

[0057] The microcontroller operatively linked to the rhythmic performance training platform 101 to continuously process real-time input signals including angular orientation and applied pressure parameters. Upon detection of any deviation, inaccuracy, or misalignment in the user’s performance with respect to predefined threshold values, the microcontroller generates and communicates corrective guidance signals. The corrective guidance assists the user in adjusting movements instantaneously, thereby enhancing precision, and minimizing errors during rhythmic performance practice or training activities.

[0058] The imaging unit 102 configured to detect the presence of multiple users positioned on the platform 101. Upon such detection, the imaging unit 102 generates and displays a query prompt for initiating a group training session. Upon receiving user confirmation through the interface, the microcontroller activates and control synchronized training and guidance protocols. The protocols include the generation of multiple holographic projections, in combination with coordinated ring arrangements, to deliver interactive visual cues and structured instructions, thereby facilitating collective practice, maintaining rhythm synchronization, and ensuring effective engagement of multiple participants simultaneously.

[0059] Moreover, a battery is associated with the system to supply power to electrically powered components which are employed herein. The battery is comprised of a pair of electrodes known as a cathode and an anode. A voltage is generated between the anode and cathode via oxidation/reduction and thus produces the electrical energy to provide to the system.

[0060] The present invention works best in the following manner, where the system comprises a base platform 101 placed on a ground surface to support one or more users during rhythmic performance routines. The platform 101 integrates the user interface within the computing unit, enabling the user to initiate training, select rhythmic performance styles, and enter relevant information. The microcontroller governs the system by processing user input and sensor data to provide real-time feedback and corrective guidance. The platform 101 further houses the AI-powered imaging unit 102 synced with the NIR sensor to detect user presence, facial expressions, body movements, and group formations, while the foldable display unit 103 mounted on extendable rods 104 deploys through the motorized scissor arrangement 105 to display demo videos. The wearable training suit 106 fitted with motorized pivot joints 108, motion sensors, and vibrating units assists the user in achieving synchronized body movements and technique improvement. The wearable training shoes 109 equipped with gyroscope and load sensors monitor foot orientation, rhythm, and pressure distribution. The circular ring-based training arrangement mounted on the platform 101 adjusts through the extendable bar 110 and dual-axial slider 112 to guide movement coordination. The holographic projection unit 113 provides a virtual partner or audience, while embedded platform 101 pressure sensors and inflatable cushion pads further enhance user safety, rhythm correction, and interactive training.

[0061] 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 rhythmic performance training system, comprising:

i) a base platform 101 structured to be placed on a ground surface, configured to support one or more users performing various rhythmic performance routines;
ii) an AI (artificial intelligence)-powered imaging unit 102 synced with a NIR (near infrared) sensor, mounted on the platform 101 to detect user presence, facial expressions, body movement, and group formations on the platform 101;
iii) a foldable display unit 103 placed on a pair of vertical extendable rods 104 provided with the platform 101, configured to deploy via an integrated motorized scissor arrangement 105 and display demo videos of selected rhythmic performance styles;
iv) a wearable training suit 106 associated with system worn by the user, to assist a user in improving rhythmic performance form, technique, and performance during rhythmic performance training;
v) a pair of wearable training shoes 109 associated with the system, worn by the user to monitor footwork accuracy, rhythm, and posture during rhythmic performance training;
vi) a circular ring-based movement training arrangement integrated with the system and mounted on the platform 101, configured to assist a user during rhythmic performance training by providing a target for movement coordination and enabling performance correction during rhythmic performance steps; and
vii) a microcontroller configured to process data from sensors and user inputs, manage overall system operations, control output components, and deliver real-time feedback.

2) The system as claimed in claim 1, wherein a user interface is inbuilt within a computing unit, configured to receive input commands from the user for initiating rhythmic performance practice, selecting rhythmic performance styles, and entering other relevant information for personalized training and system interaction.

3) The system as claimed in claim 1, wherein the wearable training suit 106 comprises of:
a) a plurality of plates 107 interconnected by motorized pivot joints 108 aligned with the body's natural joint positions to enable synchronized movement of the user's body parts,
b) an integrated motion sensor embedded within the suit 106 to detect and track subtle body movements during rhythmic performance practice, and
c) a plurality of vibrating units attached to the pivot joints 108 to provide haptic feedback for guiding the user’s movement during rhythmic performance steps.

4) The system as claimed in claim 1, wherein the wearable training shoes 109 includes:
a) a gyroscope sensor configured to measure the angular orientation of the user's foot to detect misalignment during specific rhythmic performance steps, and
b) a plurality of integrated load sensors positioned at the toe, front, and heel regions of the shoes 109, adapted to detect pressure distribution and foot placement during footwork execution.

5) The system as claimed in claim 1, wherein at least one holographic projection unit 113 mounted via a vertical extendable link 114 coupled with a universal joint to rotate and project either a holographic rhythmic performance partner or virtual audience for user interaction and feedback.

6) The system as claimed in claim 1, wherein circular ring-based movement training arrangement comprises of:
a) an extendable vertical bar 110 integrated with a circular ring 111 to adjust the height of the circular ring 111 based on the user's profile and selected rhythmic performance movements, and
b) a dual-axial horizontal slider 112 configured to laterally reposition the circular ring 111 to align with various rhythmic performance routines.

7) The system as claimed in claim 1, wherein a plurality of pressure sensors is embedded in the platform 101, configured to detect timing and rhythm of user's foot taps, and upon discrepancy with rhythm of demo video, the microcontroller replays the specific step for correction.

8) The system as claimed in claim 1, wherein a plurality of inflatable cushion pads is housed within rectangular tubes are arranged around the platform 101, upon detecting loss of balance by the user, the microcontroller inflates the pads to provide protective support against fall or injury.

9) The system as claimed in claim 1, wherein linked with the system to provide real-time corrective guidance upon detection of inaccurate angle or pressure application during a rhythmic performance movement.

10) The system as claimed in claim 1, wherein the imaging unit 102 detects presence of multiple users on the platform 101 and displays a query for initiating group training, and upon receiving confirmation, the microcontroller activates synchronized training and guidance using multiple holographic projections and ring arrangements.