Recently, Professor Ren Tianling from the Department of Microelectronics of Tsinghua University published an article entitled "Highly Sensitive and Wide Linear Range Graphene Pressure Sensor with Bionic Acupuncture Random Distribution Structure" at the ACS Nano (Epidermis Microstructure Inspired). The research results of Graphene Pressure Sensor with Random Distributed Spinosum for High Sensitivity and Large Linearity proposed a similar biomimetic structure based on the human sensory micro-structure, and solved the conflict between sensitivity and linear range through the combination of micro-structure and distribution model. It provides a brand-new idea for comprehensive improvement of mechanical device performance. In recent years, flexible mechanical micro-nanosensors have become a research hotspot in the field of human physiological information monitoring and detection. At the same time, a large number of related industrial companies have also been established. Compared with traditional silicon-based devices, they are widely used in the monitoring of human physical and chemical activities because of their characteristics of comfort, fit and wearability, but they are two important indicators of mechanical devices: sensitivity and linearity. The contradiction between them has not been well resolved. Generally prepared devices need to sacrifice one index and serve to improve another index, which often limits the scope of its practical application, and solving this contradiction becomes a research difficulty. (Top to bottom, left to right) Schematic representation of the skin's microstructure, photographs of the skin's microstructure and bionic structure, linearity and sensitivity compared to predecessors' performance, wrist pulse and respiratory monitoring results Ren Tianling's research group based on the human skin, especially the high sensitivity of fingertips to different sizes of stress response characteristics, according to the study of its microstructure proposed a similar structure. Using a sandpaper as a template to mold the flexible substrate and using graphene oxide as a mechanically sensitive layer after reduction at high temperature, a pressure sensor with acupuncture topography and random distribution was prepared. The sensor exhibits excellent stability, fast response and low detection limit, achieving high sensitivity over a wider linear measurement range. The sudden change of the contact area between the acupuncture structures contributes a high sensitivity, and the random distribution mainly contributes to a wide linear range. The combination of the two resolves this contradiction to a large extent. Due to the high sensitivity and wide linear range of the sensor, the research team successfully applied to the monitoring of various physiological activities of the human body, such as pulse, respiratory and voice recognition, and also realized the monitoring of walking, running, and jumping walking postures. And monitoring of walking gait. The use of wearable high-performance mechanical sensors for the acquisition of various physical activity parameters of the human body will have important practical significance in personal health and medical care, and has great application prospects. The research results have been supported by the key projects of the National Natural Science Foundation and the Ministry of Science and Technology. Tubular Balloon Padder Squzeeing Machine HESHAN CITY HONGFA COMPLETE SOLUTIONS MACHINE LTD. , https://www.hshongfamachine.com