Description:Field of the Invention

The present invention relates to wearable devices for monitoring and analyzing physical performance. More specifically, it concerns a system designed for tracking athletic performance in female athletes, incorporating physiological and movement data analysis along with menstrual cycle tracking.

Background of the Invention and Prior Art

In recent years, sports technology has advanced significantly, with an increasing focus on enhancing athletic performance through data-driven insights. Traditional methods of tracking athletic performance primarily relied on manual observation and subjective assessments, which often lacked precision and comprehensive data. With the advent of wearable technology, there has been a shift toward real-time monitoring of various physical parameters, providing athletes and coaches with more accurate data. However, current wearable devices are often limited in scope and fail to deliver a comprehensive view of an athlete's overall performance, especially when considering the unique physiological needs of female athletes.

Female athletes experience specific physiological changes throughout the menstrual cycle, which can impact their performance in various ways. Hormonal fluctuations during different phases of the menstrual cycle affect factors such as muscle strength, coordination, flexibility, and endurance. These fluctuations can influence ligament laxity, joint stability and the risk of injury, making it essential to consider them in training and competition strategies. However, existing wearable devices and performance monitoring systems do not account for these physiological variations, resulting in a lack of personalized feedback tailored to female athletes.
Moreover, traditional wearable devices and applications may track general performance metrics but do not integrate menstrual cycle data or provide meaningful insights into how these physiological changes impact performance. Current methods for menstrual cycle tracking lack the ability to correlate cycle phases with performance trends effectively. This gap in technology prevents female athletes from optimizing their training and competition strategies based on their specific physiological needs, which can lead to suboptimal performance and increased injury risk.

Additionally, there is often discomfort among female athletes when discussing menstrual cycle details with coaches or trainers, which can result in a lack of communication about their current physiological state. This communication gap may lead to inappropriate training regimens that do not consider the athlete's menstrual cycle, potentially affecting performance and well-being. Therefore, there is a growing need for a solution that not only tracks performance data accurately but also integrates menstrual cycle information to provide personalized feedback and recommendations.

The present invention addresses these shortcomings by introducing a comprehensive wearable device that integrates advanced sensors for accurate data collection and seamless connectivity with mobile device. It includes a specialized feature for menstrual cycle tracking, allowing female athletes to input cycle information and receive customized recommendations. This innovation offers a holistic approach to performance monitoring, combining general athletic performance metrics with menstrual cycle-specific insights to enhance the overall well-being and performance of female athletes.

Summary of the Invention

The present invention relates to a wearable device and system designed to enhance athletic performance tracking and analysis, particularly for female athletes. The invention integrates advanced sensors technology with a personalized monitoring system that incorporates real-time physical performance metrics and hormonal fluctuations associated with the menstrual cycle. This comprehensive approach ensures tailored recommendations for optimizing training, recovery, and overall athletic well-being.

The invention addresses the critical limitation of existing wearable devices, which primarily focus on general physical metrics and fail to account for the influence of hormonal variations on athletic performance. This gap in technology is particularly significant for female athletes, whose performance and recovery are heavily influenced by the menstrual cycle. By integrating menstrual cycle tracking with physical performance data, the invention overcomes this limitation, offering a holistic and precise solution for athletic performance monitoring.

The wearable device comprises a motion sensor, heart rate sensor, GPS antenna, BLE (Bluetooth Low Energy) chip, and a specialized adjustable sports vest (Footrax Vest) that houses the device securely during athletic activity. The device collects data such as heart rate, movement patterns, and location in real-time. The menstrual cycle tracking unit processes hormonal cycle data, manually input by the athlete with a mobile device.

The system communicates via BLE to a connected mobile device, where the collected data is analyzed using computational models. These computational models correlate physical performance metrics with hormonal data to generate personalized insights and recommendations. For instance, during the luteal phase of the menstrual cycle, the system may recommend lighter training loads and emphasize recovery strategies, while during the follicular phase, it might suggest more intense workouts.

Operation of the device is simple and intuitive. The athlete wears the sports vest with the embedded device and pairs it with the mobile device via a QR code located on the device. Once connected, the system begins recording physical metrics and syncing with the menstrual cycle tracking unit. Coaches can also receive notifications and session feedback via the mobile device, enabling better training management and athlete support.

This invention not only provides athletes with a deep understanding of their performance and recovery needs but also empowers coaches to plan training sessions more effectively. The integration of hormonal cycle data with physical performance metrics offers a non-obvious, innovative solution that bridges the gap in current performance monitoring technologies. This ensures smarter, more efficient training, reduced injury risk, and optimized athletic outcomes, representing a significant advancement in the field of sports performance analysis.

The inventive step lies in the seamless integration of menstrual cycle tracking with detailed performance metrics to deliver actionable insights. By processing data specific to each menstrual phase, the system tailors training and recovery strategies to the athlete's physiological state. For example, during the follicular phase, the system may recommend intensive workouts, while during the luteal phase, it suggests recovery-oriented strategies.

Objectives of the Invention

• The present invention aims to provide a highly advanced wearable device for comprehensive athletic performance tracking and analysis.
• The invention integrates a menstrual cycle tracking unit, enabling female athletes to input menstrual cycle data and correlate it with performance metrics.
• Personalized recommendations are provided based on menstrual cycle phases to optimize training, nutrition, and recovery strategies.
• The mobile device includes separate modules for athletes and coaches, enhancing communication and training planning.
• Detailed graphical representations and summary statistics of performance trends are offered, aiding data-driven decision-making.
• The invention supports adaptation of training methodologies and maximizes performance potential while promoting overall well-being.

List of drawings:

Figure 1: Top View of the Wearable Device Circuit Board
Figure 2: Back View of the Wearable Device Circuit Board
Figure 3: Front View of the Footrax Device
Figure 4: Detailed View of the Charging Port on the Footrax Device
Figure 5: Placement of QR Code on the Wearable Device
Figure 6: Coach Notification Interface for Player Sessions/Feedback
Figure 7: Personalized Training Session Screen on the Mobile Device
Figure 8: Menstrual Cycle Tracking Unit
Figure 9: Recommendations Unit
Figure 10: Integration of Footrax Device into Sports Vest
Figure 11: Adjustable Footrax Vest with Integrated Heart Rate Sensor
Figure 12: Coach Module Interface Showing Player Statistics and Performance Metrics

Name of the components as mentioned in drawings, according to numbers:

1. USB Connector
2. Charging IC
3. BLE Chip
4. GPS Antenna
5. Mounting Hole
6. Mounting Hole
7. BLE Antenna
8. Mounting Hole
9. Motion Sensor
10. FPC Connector
11. Blue Light Indicator - Indicates that the device is syncing data.
12. Red Light Indicator - Indicates that the device is charging.
13. Green Light Indicator - Indicates that power is turned on.
14. Membrane
15. Charging Port
16. QR Code - Scan to connect smartphones.
17. Notification to Coaches - About the players' session/feedback.
18. Personalized Training Sessions - To manage workload.
19. Menstrual cycle tracking unit
20. Recommendations unit
21. Specialized Adjustable Footrax Vest
22. Footrax in the Sports Vest
23. Heart Rate Sensor

Detailed description of the drawings

In this patent application, a total of 11 drawings have been provided to offer a comprehensive view of the Footrax Wearable Device, illustrating its external and internal components. Each drawing is numbered to facilitate clear reference to the corresponding parts and their functions.

Figure 1 presents a top view of the Footrax device's circuit board. This figure highlights several critical components, including the USB Connector (01), which is utilized for charging the device. The Charging IC (02) is depicted, responsible for managing the charging process and ensuring the battery's optimal performance. The BLE Chip (03) is shown, enabling Bluetooth communication for seamless data transfer. The GPS Antenna (04) is illustrated, providing GPS functionality for accurate location tracking. Additionally, multiple Mounting Holes (05, 06, 08) are visible, designed to secure the device within its housing. The BLE Antenna (07) is also highlighted, enhancing signal strength and connectivity.

Figure 2 offers a back view of the circuit board, showcasing the Motion Sensor (09), which detects movement and contributes to performance metrics. The FPC Connector (10) is included in this view, serving as the interface for connecting the circuit board to other components of the device.

Figure 3 displays the front of the Footrax device. This figure features several indicator lights: the Blue Light Indicator (11) signals data synchronization status, the Red Light Indicator (12) shows the charging status, and the Green Light Indicator (13) represents the power status. The Membrane (14) is shown as a protective layer covering the device, safeguarding internal components from environmental factors.

Figure 4 provides a detailed view of the Charging Port (15), illustrating its design and placement on the device. This port is crucial for connecting the device to a power source for charging.

Figure 5 emphasizes the placement of the QR Code (16) on the device. This QR code plays a vital role in ensuring secure and exclusive connectivity between the device and the mobile device by encoding the device’s unique MAC address.

Figure 6 illustrates the interface screen that notifies coaches about player sessions and feedback (17). This screen is part of the mobile device, designed to display real-time insights and performance data to coaches.

Figure 7 shows the Personalized Training Session Screen (18) within the mobile device. This screen provides tailored training recommendations and session details based on the data collected from the Footrax device.

Figure 8 depicts the menstrual cycle tracking unit (19), which allows female athletes to input detailed information about their menstrual cycles. This unit integrates with the device to correlate cycle data with performance metrics.

Figure 9 provides a view of the Recommendations Unit (20), which processes the collected data and generates personalized training and performance recommendations.

Figure 10 illustrates the integration of the Footrax Device into a Sports Vest (22). This figure shows how the device is incorporated into the vest, allowing for comfortable and effective wear during athletic activities.

Figure 11 depicts the Adjustable Footrax Vest (21) equipped with an Integrated Heart Rate Sensor (23). This vest is designed for versatility and comfort, with the heart rate sensor providing additional performance metrics.

Figure 12 depicts the Coach Module Interface, which showcases player statistics and performance metrics. This interface is an integral part of the wearable performance tracking system, enabling coaches to monitor and analyze multiple players' data on a single dashboard.
These detailed descriptions of the drawings ensure a thorough understanding of each component and its function within the Footrax Wearable Device, underscoring the innovation and utility of the invention.

Detailed description of Invention

The present invention pertains to a Wearable Device designed to elevate the tracking and analysis of athletic performance, particularly for female athletes. This advanced system integrates a range of sensors, connectivity features, and a mobile device to offer real-time data collection, personalized analysis, and recommendations for optimizing training and performance. The device not only tracks standard athletic metrics like speed, distance, and heart rate but also incorporates a unique menstrual cycle tracking unit (19), providing tailored insights based on the athlete’s physiological changes.

At the core of the wearable device is an integrated sensors system that works in unison to monitor and record various aspects of an athlete’s physical performance. This includes an accelerometer, which measures acceleration by capturing speed and direction, enabling a detailed analysis of motion patterns during activities such as sprints, deceleration, and directional changes. A gyroscope complements this by detecting rotational movements, helping to analyze stability and balance during complex maneuvers such as pivots and twists. The system also features a GPS sensor (4) that provides accurate location tracking, enabling the device to map spatial data, such as the distance covered and route efficiency, particularly useful in outdoor sports. Additionally, a heart rate monitor sensor (23) tracks cardiovascular metrics, offering insights into endurance, recovery times, and overall cardiovascular health. These sensors work together to provide a comprehensive picture of athletic performance, with the data being processed and analyzed through the accompanying mobile device.

The device is equipped with advanced connectivity features to ensure seamless communication with external devices. A Bluetooth Low Energy (BLE) antenna (7) allows for real-time wireless transmission of data to a mobile device while maintaining low power consumption, thus extending battery life. The BLE antenna (7) enables stable, energy-efficient communication during training and competitions, ensuring that performance data is transmitted for analysis. Additionally, a USB port (1) is included for power delivery, enabling efficient charging and ensuring that the device remains fully operational, even during extended periods of use.

A QR code (16) is embedded in the device to enable secure and exclusive pairing with the mobile device. The QR code (16) encodes the device's unique MAC address, ensuring that each wearable device is identifiable and can only connect to its designated mobile device. This mechanism enhances data security, preventing any mix-ups or data sharing between multiple devices, and ensures that the performance metrics collected are attributed to the correct user. This feature is particularly valuable in environments with multiple users, such as team sports, where it is essential to maintain the integrity of individual data.

The wearable device includes a unique feature, the menstrual cycle tracking unit (19), which is a logical unit specifically designed to address the unique physiological needs of female athletes. The menstrual cycle tracking unit (19) is configured to receive input data regarding the menstrual cycle, including start and end dates, as well as any physiological metrics that may be relevant, such as changes in energy levels, mood, or physical discomfort. Athletes can manually log detailed cycle information, and this data is securely stored in an encrypted format within the system. The encrypted storage ensures that the input data is protected and can be securely retrieved during the analysis process. This data is then cross-referenced with performance metrics collected by the device's sensors, allowing for a detailed comparison between the athlete’s physiological state and their physical performance.

By integrating this menstrual cycle data with the performance data, the menstrual cycle tracking unit (19) enables the device to provide personalized insights. These insights help identify potential correlations between menstrual cycle phases and performance variations. This integration forms the foundation for the recommendations unit (20), which processes the collected performance metrics—such as average speed, top speed, distance traveled, time played, work rate, acceleration, deceleration, speed zones, sprint count, sprint distance, workload, intensity, and heart rate—together with the cycle data. The system then applies statistical models and machine learning algorithms to assess the impact of hormonal fluctuations on physical performance. The results are used to generate phase-specific recommendations, optimizing training regimens by adjusting intensity, volume, and recovery periods. Furthermore, the menstrual cycle tracking unit (19) allows for secure and accurate monitoring of the athlete's cycle, providing data that can be utilized for more precise and personalized training strategies.

The present invention also includes a recommendations unit (20), which is a logical unit that plays a pivotal role in analyzing both physical performance metrics and menstrual cycle data to provide tailored training and competition strategies. This unit receives data from the wearable device’s sensor system, which includes performance metrics such as average speed, top speed, distance traveled, time played, work rate, acceleration, deceleration, speed zones, sprint count, sprint distance, workload, intensity, and heart rate. Additionally, it receives menstrual cycle parameters, including phase information and hormonal fluctuations. The recommendations unit utilizes statistical models and machine learning algorithms to analyze the correlations between the physical performance metrics and menstrual cycle data. By applying computational models, it assesses how hormonal fluctuations impact performance, categorizing the data into phase-specific trends. The system's ability to identify patterns in endurance, strength, recovery times, and other performance factors provides athletes with actionable insights on how their menstrual cycle may influence training outcomes.

A key feature of the recommendations unit (20) is its graphical processing module, which generates data visualizations that represent performance trends across menstrual cycle phases. These visualizations offer athletes and coaches a clear understanding of performance patterns and allow for more informed decision-making in training adjustments. Based on its analysis, the recommendations unit generates phase-specific adjustments to training parameters, including intensity and volume, optimizing training loads according to the athlete's physiological state. Furthermore, the unit computes modifications to nutrition and hydration strategies, addressing varying energy needs during different menstrual cycle phases. It also determines appropriate recovery modalities and rest periods to ensure proper recovery and minimize the risk of overtraining. The recommendations, including adjustments to training, recovery, nutrition, and hydration, are transmitted in real-time to both the athlete and coach, enabling dynamic and informed decision-making that maximizes performance while promoting overall health and well-being.

The mobile device associated with the wearable device is designed with two distinct modules to cater to both coaches and athletes, each providing specific functionalities for performance analysis and training management. The coach module (17) is configured to interface with multiple wearable devices via the QR code (16), enabling aggregated access to performance data for user-specific training analysis. This functionality allows a single mobile device to connect with and manage multiple wearable devices, each associated with a different athlete. The coach module (17) provides a centralized platform for coaches to aggregate, analyze, and compare the performance data of various athletes. By offering insights into each athlete’s progress and performance metrics, including menstrual cycle data entered by female athletes, the coach module (17) supports data-driven decision-making and enables tailored training sessions. Coaches can access the menstrual cycle information of female athletes, ensuring that menstrual cycle phases are considered when planning training regimens, which helps address the communication gap between coaches and athletes regarding their physiological states. This access also enables coaches to make adjustments to training based on the athlete's cycle, ensuring training recommendations are appropriate.

Conversely, the individual module (18) is configured to link to a single wearable device using the QR code (16), ensuring isolated access to the athlete’s personal performance data. This module ensures that all collected data remains confidential and secure, providing the athlete with a private environment to view and analyze their own performance metrics, including insights related to their menstrual cycle. Female athletes can input their menstrual cycle information, which is securely stored and accessible by both the athlete and coach. This feature improves communication, as coaches can better understand how hormonal fluctuations might be affecting performance. Additionally, the individual module (18) provides personalized feedback and recommendations related to training intensity, recovery, nutrition, and hydration based on the athlete’s menstrual cycle and performance metrics. By integrating this cycle data, the system bridges a significant gap in understanding and supports a more tailored, effective approach to training, promoting optimal performance while respecting physiological changes.

The wearable device is equipped with indicator lights that provide users with clear and immediate feedback regarding the device’s operational status. The blue light indicator (11) signals when the device is actively syncing data, ensuring that the user is aware when the data is being transmitted. The red light indicator (12) illuminates to indicate that the device is charging, providing users with a visual cue about the charging process. The green light indicator (13) signals that the device is powered on and functioning properly, allowing users to confirm the operational state of the device at any given time. These visual cues are an essential feature for user convenience, helping athletes and coaches easily monitor the device’s performance and manage usage during physical activities.

The wearable device is designed to be integrated into a specialized adjustable vest (21), enhancing both the functionality and comfort of the system during physical activity. The vest includes an adjustable heart rate sensor (23), strategically positioned to monitor the athlete’s heart rate with high accuracy. The adjustable design of the vest ensures that the heart rate sensor (23) is securely placed on the athlete’s body, allowing for precise data collection while preventing movement of the device during intense, dynamic physical activities. The vest's design accommodates various body types, ensuring a snug and secure fit, thus maintaining the integrity of data even during high-intensity movements. This secure placement is essential for maintaining the accuracy of the collected heart rate data, providing reliable metrics that contribute to the overall performance analysis of the athlete.

Method for Enhancing Tracking and Analysis of Female Athletic Performance Using the Wearable Device

1. Input Menstrual Cycle Data
o The athlete inputs menstrual cycle data, including the start and end dates, into the menstrual cycle tracking unit (19).
o The data is securely stored and cross-referenced with performance metrics for later analysis.

2. Scan QR Code for Session Activation
o The athlete scans the QR code (16) using a mobile device to access their personal profile and activate the training session.

3. Power On the Wearable Device
o The wearable device is powered on, starting real-time data collection during the athlete's physical activities.

4. Wear the Device During Activities
o The athlete wears the device during physical activities to collect real-time performance data through the integrated sensors.
o Data collected includes acceleration, deceleration, speed, distance, heart rate, and other performance metrics.

5. End the Session
o The athlete terminates the session by pressing the "end session" button on the mobile device.

6. Synchronize Data
o The recorded performance data is synchronized from the wearable device to the mobile device via Bluetooth Low Energy (BLE) at the end of the session.

7. Analyze Collected Data
o The collected performance metrics are analyzed, including: average speed, top speed, distance covered, time played, workload, acceleration, deceleration, speed zones, number of sprints, sprint distance, player intensity and heart rate
8. Correlate Performance with Menstrual Cycle Phases
o The performance data is analyzed in correlation with the athlete's menstrual cycle phases, identifying how hormonal fluctuations may impact performance.

9. Generate Phase-Specific Recommendations
o Based on the data analysis, the system generates personalized, phase-specific recommendations for:
- Adjustments to training workload and intensity
- Recovery protocols
- Nutrition and hydration strategies

10. Transmit Insights to Mobile Devices
o The insights and recommendations, including graphical summaries and statistical outputs, are transmitted to both the athlete’s and coach’s mobile devices for review.
o This allows both parties to make data-driven adjustments to training plans to optimize performance.

The invention offers numerous advantages. By correlating performance data with menstrual cycle phases, it provides personalized insights that account for the physiological changes women experience throughout their cycle. This allows female athletes to train more effectively and avoid the pitfalls of generalized training plans that may not align with their individual needs. The device's energy-efficient design, featuring the BLE chip (3), ensures long-lasting performance, while its intuitive interface and seamless synchronization simplify the user experience. Additionally, the Footrax vest (21) provides the necessary support and comfort for high-performance tracking, ensuring that the sensors are positioned optimally even during intense physical activities.

In conclusion, the present invention provides a comprehensive wearable system that tracks athletic performance and offers personalized insights, with an emphasis on addressing the specific needs of female athletes. By integrating advanced sensor technologies with menstrual cycle tracking, it offers a data-driven, scientifically-informed approach to training. This invention represents a breakthrough in sports technology, helping female athletes optimize their performance, improve their training regimens, and enhance overall athletic outcomes. , Claims:CLAIMS

I/We Claims,

1. A wearable device for enhance tracking and analysis of female athletic performance, comprising:

- a sensor assembly embedded within the device, configured to collect real-time data related to physical movement and physiological parameters;
- a GPS antenna (4) configured for accurate location tracking;
- a BLE antenna (7) configured for wireless communication with an external mobile device;
- a USB port (1) configured for power delivery;
- a QR code (16) encoded with a unique identifier, configured to establish a pairing mechanism between the wearable device and a mobile device for secure data access;
- an indicator lights configured to display data syncing status (11), charging status (12) and power status (13);
- a menstrual cycle tracking unit (19) configured to receive input data regarding the menstrual cycle, including start and end dates and physiological metrics; and
- a recommendations unit (20) configured to process physical performance data and menstrual cycle data to derive analytical outputs.

2. The wearable device for enhance tracking and analysis of female athletic performance as claimed in claim 1, wherein the sensor assembly includes a motion sensor (9), GPS sensor (4) and heart rate monitor sensor (23) configured to provide data related to parameters including acceleration, velocity, distance and cardiac activity.

3. The wearable device for enhance tracking and analysis of female athletic performance as claimed in claim 1, further comprising:

- a coach module is configured to interface with multiple wearable devices via the QR code (16), enabling aggregated access to performance data for user-specific training analysis; and
- an individual module is configured to link to a single wearable device using the QR code (16), providing isolated access to individual performance metrics.

4. The wearable device for enhance tracking and analysis of female athletic performance as claimed in claim 1, wherein the BLE antenna (7) is configured to synchronize data between the wearable device and the external mobile device upon activation of a session termination.

5. The wearable device for enhance tracking and analysis of female athletic performance as claimed in claim 1, wherein the menstrual cycle tracking unit (19) is configured to store input data in an encrypted format, enabling secure data storage and retrieval during analysis.

6. The wearable device for enhance tracking and analysis of female athletic performance as claimed in claim 1, wherein the recommendations unit (20) utilizes statistical models and machine learning to analyze correlations between physical performance metrics and menstrual cycle parameters.

7. The wearable device for enhance tracking and analysis of female athletic performance as claimed in claim 1, wherein the recommendations unit (20) processes performance metrics selected from a group consisting of average speed, top speed, distance travelled, time played, work rate, acceleration, deceleration, speed zones, sprint count, sprint distance, workload, intensity and heart rate.

8. The wearable device for enhance tracking and analysis of female athletic performance as claimed in claim 1, wherein the recommendations unit (20) applies computational models to assess the impact of hormonal fluctuations on physical metrics, enabling phase-specific data categorization.

9. The wearable device for enhance tracking and analysis of female athletic performance as claimed in claim 1, wherein the recommendations unit (20) includes a graphical processing module configured to generate data visualizations representing performance trends across menstrual cycle phases.

10. The wearable device for enhance tracking and analysis of female athletic performance as claimed in claim 1, wherein the recommendations unit (20) is configured to generate phase-specific adjustments in training parameters including intensity and volume and compute modifications to nutrition and hydration strategies, determining appropriate recovery modalities and rest periods based on physiological data variations during menstrual cycle phases and transmitting these adjustments to coaches and athletes for implementation.

11. A method for enhancing tracking and analysis of female athletic performance using the wearable device as claimed in claim 1, comprising the steps of:

- Inputting menstrual cycle data, including start and end dates, into the menstrual cycle tracking unit (19);
- Scanning a QR code (16) with a mobile device to access the athlete’s profile and activate the session;
- Powering on the wearable device to initiate real-time data recording;
- Wearing the device during physical activities to collect data through an integrated sensor assembly, wherein the data includes acceleration, deceleration, speed, distance covered, heart rate and other performance metrics;
- Terminating an active session through the mobile device by pressing an 'end session' button;
- Synchronizing the recorded data from the wearable device to the mobile device using Bluetooth Low Energy (BLE) at the end of the session;
- Analyzing the collected performance metrics and correlating them with menstrual cycle phases;
- Processing performance parameters, including average speed, top speed, distance covered, time played, workload, acceleration, deceleration, speed zones, number of sprints, sprint distance, player intensity and heart rate, to generate detailed insights;
- Generating phase-specific training recommendations, including adjustments to workload, recovery protocols, nutrition and hydration strategies, based on menstrual cycle analysis and performance data; and
- Transmitting the insights and recommendations, including graphical summaries and statistical outputs, to the mobile device for review by the athlete and coach.