技术开发

在迈射智能科技，我们采用灵活的研究团队组织方式，研究人员包括从物理学家、材料学家和化学工程师到机器学习软件开发人员和数据分析专家。该团队致力于在公司核心能源、电力等领域不断设计和开发创新技术与产品，包括各类原型机开发和持续工程问题解决，以及在新兴领域，如环保、安防等领域的不断创新。

我们的创新工作是通过将内部专业知识与世界各地的科研机构相结合来实现，我们的研究设施包括先进的材料分析、无损检测和光谱实验室用于各类光学传感及复合材料改性项目。除了日常测试项目外，该研发团队也参与各类数学建模和光学模拟测试。该研究团队致力于开发新的方法与模型，可用于及时、智能、有效地解决用户的工程问题。

目前的项目涵盖了广泛的研究课题，包括近红外及拉曼红外光谱、光纤传感、量子级联激光器、数学建模和机器学习。

Quantum cascade lasers (QCLs) are a type of semiconductor laser which utilizes epitaxially grown quantum wells that contain electrons in lasing states. They were first demonstrated in 1994 by the Bell Labs Team of Jérôme Faist, Federico Capasso, Deborah, Sivco, Carlo Sirtori, Albert Hutchinson, and Alfred Cho. The optical physics of a QCL differ from that of a diode laser. In a QCL the lasing transition occurs between states within a given quantum well. In contrast, in a diode laser transitions occur between the conduction band and valence band of the semiconductor material.

Photoacoustic spectroscopy is the measurement of the effect of absorbed electromagnetic energy (particularly of light) on matter by means ofacoustic detection. The discovery of the photoacoustic effect dates to 1880 when Alexander Graham Bell showed that thin discs emitted sound when exposed to a beam of sunlight that was rapidly interrupted with a rotating slotted disk. The absorbed energy from the light causes local heating, generating a thermal expansion which creates a pressure wave or sound.

Laser vibrometry is a method used for non-contact vibration measurements. As the measurement made with a laser vibrometer is non-intrusive and non-destructive it has many fields of application. Applications include automotive industry, architecture, aerospace, security and many others. One of the first inventions in laser vibrometry application in security would be the “Buran”eavesdropping system created by a Soviet inventor Leon Theremin for which he received the First Class Stalin Prize. This system used an infrared laser to covertly detect speech from a window of a room in which people were conversing. It is believed that the system was used to eavesdrop on American and French embassies as well as Stalin himself. It is considered that this system is the original predecessor of the modern laser microphones.

It’s called hyperspectroscopy, and it aims to identify objects based solely off of the light information that they emit into the world. At this point you might say, “Yeah, that’s a telescope, so what”? The trick here lies in the fact that there’s much more to light than wavelengths we can actually see. a Next-Generation Airborne Visible/Infrared Imaging Spectrometer. You take this fancy device, point it at the leaves, and voila –this is what you see.

Fiber optic distributed sensors measure temperature only (Raman Optical Time Domain Reflectometry - ROTDR) or both strain and temperature (Brillioun Optical Time Domain Reflectometry - BOTDR). Spatial resolution is typically one meter or more and strain and temperature resolution are reported at about one microstrain and one degree C respectively, with sampling rates of a few seconds per measurement. The beauty of these approaches is that standard (i.e., inexpensive) telecom fiber is the sensor. The fiber is usually packaged in a tough outer jacket for deployment. Instrumentation is often US$100,000 or more, however. But still the value is very good for long range (>2 km) applications such as pipelines, tunnels, power transmission lines.

​Ecometrics is the quantitative analysis of economic, environmental, and societal systems based on the concurrent development of empirical theory, related by appropriate methods of inference in attempts to create more sustainable systems. Broadly defined, Ecometrics is a way to evaluate if an activity is contributing to more sustainable systems of production and consumption. Ecometrics is a system of statistical extrapolation and interpolation that uses principles of resource management in economic and environmental studies to analyze trends in consumption.

在迈射智能科技，我们采用灵活的研究团队组织方式，研究人员包括从物理学家、材料学家和化学工程师到机器学习软件开发人员和数据分析专家。该团队致力于在公司核心能源、电力等领域不断设计和开发创新技术与产品，包括各类原型机开发和持续工程问题解决，以及在新兴领域，如环保、安防等领域的不断创新。 我们的创新工作是通过将内部专业知识与世界各地的科研机构相结合来实现，我们的研究设施包括先进的材料分析、无损检测和光谱实验室用于各类光学传感及复合材料改性项目。除了日常测试项目外，该研发团队也参与各类数学建模和光学模拟测试。该研究团队致力于开发新的方法与模型，可用于及时、智能、有效地解决用户的工程问题。

"Zero drift NDIR gas sensors," Jacob Y. Wong & Mike Schell, Sensor Review Vol. 31 No.1, 2012 pp.70-77 http://www.emeraldinsight.com/journals.htm?articleid=1902872 "Recalibration technique for NDIR gas sensors without the need for gas standards," Jacob Y. Wong & Chi Wai Tse, Sensor Review Vol. 32, No. 3, 2012 pp.217 - 221. http://www.emeraldinsight.com/journals.htm?articleid=17026092

MASER TECHNOLOGY是经验丰富的定制开发项目合作伙伴，可根据用户具体要求定制研究和开发方案，自成立之初，MASER TECHNOLOGY就已参与了与智能材料、仪器及检测技术相关的定制开发项目。