Blautic Photoplethysmography

An advanced electronic device system designed for physiological and biomechanical monitoring in health, sports, and wellness settings.

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A flexible solution for health, sports, and wellness

Optical, motion, and wireless communication sensors
The system integrates state-of-the-art optical and motion sensors, together with wireless communication platforms and mobile applications that enable real-time data acquisition, visualization, and analysis.

PPG or NIRS optical sensors
Capable of using light sources in the red, green, and infrared bands, or multiband near-infrared, to detect photoplethysmographic signals or tissue oxygenation.
These technologies enable the estimation of parameters such as heart rate, pulse variability (HRV), peripheral perfusion, or oxygen saturation (SpO₂), depending on the system design and calibration.

Inertial sensors (accelerometer and gyroscope)
Provide information on movement, physical intensity, posture, and orientation, enabling analysis of the body’s response and synchronization between physiological and mechanical activity.

Architecture and connectivity

The solutions are based on a modular architecture that combines:

  • Multisensory data acquisition with time synchronization between optical and inertial signals.
  • Wireless transmission to mobile devices, which act as reception, visualization, and storage nodes.
  • Open communication protocols and standard data formats, facilitating integration into external systems, analytics platforms, or third-party solutions.

Application and data visualization

A mobile app and complementary software environment enable:

  • Real-time visualization of physiological and motion parameters.
  • Historical logging and session management.
  • Advanced processing of metrics such as heart rate, HRV, oxygenation, movement intensity, or energy expenditure.
  • Data transmission to servers or IoT platforms for aggregated analysis or research.

Application areas

  • Health and wellness: development of wearables for personal tracking, rehabilitation, or telecare.
  • Sports and performance: devices for training, recovery, and cardiodynamic analysis.
  • Biomedical and scientific research: experimental platforms for applied physiology studies.
  • Fitness and medical technology industry: integration into monitoring ecosystems and digital health platforms.

Key advantages and differentiating capabilities

  • Technological flexibility: the ability to combine different configurations of optical and inertial sensors.
  • Scalability: adaptation to portable, textile, modular formats or integration into other devices.
  • Advanced signal processing: extraction of robust physiological metrics under real-world movement conditions.
  • End-to-end software-hardware integration: from electronic design to the user interface and analysis algorithms.

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