Product Features

Applied to vital sign monitors, wearable health devices (blood pressure monitors, heart rate monitors, glucose meters), portable emergency equipment and rehabilitation training instruments. These circuits feature low power consumption, miniaturization, high sensitivity and easy portability. They can accurately collect key physiological data (heart rate, blood pressure, blood glucose, oxygen saturation) and transmit data stably, adapting to hospital monitoring, home care, elderly care and outdoor emergency scenarios.

Technical & Technological Advantages

Adopt low-power circuit design to extend the battery life of wearable and portable medical devices; use high-density miniaturized wiring to fit the compact structure of wearable products and improve wearing comfort; integrate high-sensitivity signal acquisition circuits and noise filtering technology to reduce detection errors; apply waterproof, sweat-proof and anti-interference packaging technology to adapt to daily wearing and complex environmental conditions; support wireless communication protocols (Bluetooth, Wi-Fi) for real-time data upload and remote monitoring.

Application Scenarios

Hospital intensive care units (ICUs) for real-time monitoring of patients’ vital signs and abnormal early warning; home wearable health devices for daily health monitoring and chronic disease management (hypertension, diabetes); portable emergency equipment for outdoor and home first aid, assisting in rapid physiological data collection and emergency response; rehabilitation training instruments for precise rehabilitation guidance and progress tracking of patients with motor disorders.

Production & Application Challenges

Balancing miniaturization, low power consumption and high sensitivity is extremely difficult, often leading to data inaccuracies or insufficient battery life; long-term contact with the human body requires both wearing comfort and waterproof/sweat-proof performance, increasing process design complexity; simultaneous collection of multiple physiological signals is prone to cross-interference, requiring complex signal fusion and debugging; civil wearable medical devices need to balance medical compliance and cost-effectiveness, making cost control a key challenge.