As people pay more attention to health, there is an increasing demand for medical electronic products in the market, especially a rapid growth of high-end products, such as CT scan, MRI, top grade ultrasonic diagnosis instrument, etc.
It has significantly enlarged market size of global medical electronic instrument. Espicom, a market research organization forecasts that the global medical instrument market volume will exceed USD 200 billion, among which medical electronic products will account for 45%, hitting USD 90 billion.
In the perspective of Chinafs market, accelerated market growth, hospital informationalization progress and related state policy changes have exerted favorable influence.
Chinafs medical electronic market continued to expand in the year of 2006. Its sales volume exceeded RMB 20 billion, reaching RMB 21.08 billion, up by 15.6% over the previous year, obviously higher than the growth of the same kind of market of the world. In the coming years, Chinafs medical electronic market will continue to grow steadily, with the CAGR (compound annual growth rate) of 18.2%, and in the year of 2011, Chinafs medical electronic market volume will be expected to approach RMB 50 billion.
The medical electronic market growth has fueled the development of the industries such as medical electronic semiconductors, components, materials and manufacturing equipment, etc.
In the coming five years, the medical electronic semiconductor market will grow at the CAGR of 11%. Its volume will exceed USD 3.5 billion. To meet strict demands on steadiness and performance of medical electronic equipment, safety of equipment and userfs body and specific demands on certification of medical system, higher requirements have been set for medical electronic elements and design programs as well as materials and production technologies, etc.
Because of the development trend of small size and better portability, there will be a higher requirement on power consumption and signal processing. Engineers will thus meet a bigger challenge.
Medical Electronics IC & Components, including Sensor, Passive Components,, Modules, etc.;
Medical Electronics Test & Measurement Instruments;
Advanced Materials Applied in Medical Electronics
For more information:ConvergEvent
ILA Goes Digital – Automation & Production Technology for Adaptable Aircraft Production
29.06.2020 | Fraunhofer-Gesellschaft
Special exhibition area "Microtechnologies for Optical Devices" establishes itself at W3
12.03.2020 | IVAM Fachverband für Mikrotechnik
Scientists at the Fraunhofer Institute for Laser Technology ILT have come up with a striking new addition to contact stamping technologies in the ERDF research project ScanCut. In collaboration with industry partners from North Rhine-Westphalia, the Aachen-based team of researchers developed a hybrid manufacturing process for the laser cutting of thin-walled metal strips. This new process makes it possible to fabricate even the tiniest details of contact parts in an eco-friendly, high-precision and efficient manner.
Plug connectors are tiny and, at first glance, unremarkable – yet modern vehicles would be unable to function without them. Several thousand plug connectors...
An international research team has found a new approach that may be able to reduce bone loss in osteoporosis and maintain bone health.
Osteoporosis is the most common age-related bone disease which affects hundreds of millions of individuals worldwide. It is estimated that one in three women...
Traditional single-cell sequencing methods help to reveal insights about cellular differences and functions - but they do this with static snapshots only...
“Core-shell” clusters pave the way for new efficient nanomaterials that make catalysts, magnetic and laser sensors or measuring devices for detecting electromagnetic radiation more efficient.
Whether in innovative high-tech materials, more powerful computer chips, pharmaceuticals or in the field of renewable energies, nanoparticles – smallest...
An international research team with Prof. Cornelia Denz from the Institute of Applied Physics at the University of Münster develop for the first time light fields using caustics that do not change during propagation. With the new method, the physicists cleverly exploit light structures that can be seen in rainbows or when light is transmitted through drinking glasses.
Modern applications as high resolution microsopy or micro- or nanoscale material processing require customized laser beams that do not change during...
23.07.2020 | Event News
21.07.2020 | Event News
07.07.2020 | Event News
06.08.2020 | Earth Sciences
06.08.2020 | Power and Electrical Engineering
06.08.2020 | Life Sciences