MEMS sensors are built into every smartphone but can also play a significant role in industrial technology. They have greatly expanded our ability to detect certain mechanical parameters and respond to them very quickly. But what exactly is the technology behind the acronym MEMS, and what currently untapped possibilities do they offer for professional applications?
The three-axis accelerometer from DIS Sensors is explicitly based on MEMS technology
(Image: Reichelt Elektronik)
MEMS sensors make it easy to change the screen orientation of a smartphone simply by rotating it. Hardly anyone is unfamiliar with this feature, as it is used daily. On the other hand, few people know how this mechanism works and the diverse applications MEMS technology offers beyond this.
Indispensable for Digitalization
Especially in industrial applications, MEMS technology can make a significant contribution to the digital transformation of the economy through data-driven manufacturing. To generate high added value, production systems must process as many, sometimes very diverse, types of data as possible in a value-adding manner. Sensors and transducers serve as information sources.
They provide the higher-level systems with information about physical parameters and plant conditions as a basis for decision-making in control and regulation, as well as plant operation and maintenance. In this way, MEMS sensors can help prevent machine downtime and quality issues while increasing sustainability through improved manufacturing and energy efficiency.
Sensor Technology With Growing Importance
Detecting and measuring physical parameters often requires converting the measured variable into an electrical signal. In the past, this frequently required very complex precision mechanical arrangements. These were often large and expensive, making their integration into compact mechatronic units challenging.
Especially in mechanical and plant engineering, the integration of additional sensors was met with skepticism, as every added complexity was considered a potential cause of failure. Furthermore, the processing power of control electronics was limited. These restrictions, however, are now a thing of the past.
Not only in mechanical and plant engineering but in general, it has become evident that increasing the efficiency and effectiveness of devices, machines, and systems is only possible with a broader data base.
Revolution Through Micro-Electromechanics
The widespread use of sensors—particularly for three-dimensional measurements required in applications such as mechanical engineering, robotics, or aerospace—is made possible through their miniaturization. Here, MEMS technology plays a leading role. MEMS sensors are extremely small. They can be manufactured alongside electronics for preprocessing the collected data and offered in an extremely compact form.
But what exactly is MEMS? The English abbreviation "MEMS" stands for Microelectromechanical Systems, meaning very small mechatronic systems. They emerged as a result of a technological shift. When classical precision engineering reached the limits of physical feasibility about 40 years ago, the well-established manufacturing processes of the semiconductor industry were utilized to produce extremely small and yet quite complex mechanical structures.
That was the birth of microsystem technology, which integrates electronic, mechanical, and optical components into the smallest spaces. It has made practically invisible hearing aids possible with extremely small microphones and speakers and brought forth tiny actuators used, for instance, to create pumps or motors for medical purposes that can be integrated into blood vessels. MEMS technology is also a significant branch of microsystem technology.
Monolithic Manufacturing—MEMS from A Single Mold
MEMS sensors are manufactured like semiconductor chips using etching processes on silicon wafers. As with semiconductors, the process is repeated multiple times with different masks to create 3D structures. By successively removing material, structures containing movable parts can be created.
The special feature is that these parts are no longer manufactured individually and then assembled as was traditionally done. Instead, they are created as a whole from a single block. This not only allows them to be significantly smaller but also eliminates the need for creating connections or simplifies and enhances precision through the subtractive process (removing everything that is not part of the sensor or a supporting auxiliary structure).
Reliable Conclusions
The basic principle is the same for all MEMS sensors. They measure the effect of the measured variable on the position or movement of their fixed and movable parts relative to each other. For this purpose, these parts are shaped during the manufacturing process so that their surfaces form a capacitor. Since this is very small due to the microscopic dimensions, these surfaces are often arranged in multiples. This can basically be imagined as two interlocking combs forming the electrodes.
Date: 08.12.2025
Naturally, we always handle your personal data responsibly. Any personal data we receive from you is processed in accordance with applicable data protection legislation. For detailed information please see our privacy policy.
Consent to the use of data for promotional purposes
I hereby consent to Vogel Communications Group GmbH & Co. KG, Max-Planck-Str. 7-9, 97082 Würzburg including any affiliated companies according to §§ 15 et seq. AktG (hereafter: Vogel Communications Group) using my e-mail address to send editorial newsletters. A list of all affiliated companies can be found here
Newsletter content may include all products and services of any companies mentioned above, including for example specialist journals and books, events and fairs as well as event-related products and services, print and digital media offers and services such as additional (editorial) newsletters, raffles, lead campaigns, market research both online and offline, specialist webportals and e-learning offers. In case my personal telephone number has also been collected, it may be used for offers of aforementioned products, for services of the companies mentioned above, and market research purposes.
Additionally, my consent also includes the processing of my email address and telephone number for data matching for marketing purposes with select advertising partners such as LinkedIn, Google, and Meta. For this, Vogel Communications Group may transmit said data in hashed form to the advertising partners who then use said data to determine whether I am also a member of the mentioned advertising partner portals. Vogel Communications Group uses this feature for the purposes of re-targeting (up-selling, cross-selling, and customer loyalty), generating so-called look-alike audiences for acquisition of new customers, and as basis for exclusion for on-going advertising campaigns. Further information can be found in section “data matching for marketing purposes”.
In case I access protected data on Internet portals of Vogel Communications Group including any affiliated companies according to §§ 15 et seq. AktG, I need to provide further data in order to register for the access to such content. In return for this free access to editorial content, my data may be used in accordance with this consent for the purposes stated here. This does not apply to data matching for marketing purposes.
Right of revocation
I understand that I can revoke my consent at will. My revocation does not change the lawfulness of data processing that was conducted based on my consent leading up to my revocation. One option to declare my revocation is to use the contact form found at https://contact.vogel.de. In case I no longer wish to receive certain newsletters, I have subscribed to, I can also click on the unsubscribe link included at the end of a newsletter. Further information regarding my right of revocation and the implementation of it as well as the consequences of my revocation can be found in the data protection declaration, section editorial newsletter.
With the distance between the electrodes changing, its capacitance is altered. This can be measured, and deviations from the normal value provide information about the relative position of the parts to each other. Through inertia, this enables conclusions to be drawn about the acceleration to which this arrangement is subjected.
Due to the material properties of the silicon crystals used and the applied exposure and etching processes, fluctuations and external influences play a minor role. This allows for the production of sensors that deliver consistently high measurement quality over very long periods and enable reliable conclusions about the mechanical measurement variables.
The functioning structures in MEMS sensors can be designed to be highly sensitive for measurements. Nevertheless, MEMS sensors are available in extremely robust, industrial-grade designs. Since many of them have no freely moving parts or joints in between, they are also resistant to vibrations and temperature fluctuations.
MEMS sensors are now very widespread and found in many applications. MEMS technology is primarily used in accelerometers and gyroscopes, but also in flow, pressure, inclination, and temperature sensors, as well as sensors for gas composition or air quality. It is not always obvious that MEMS sensors are involved. They can be a deeply integrated part of more complex electronic modules or products, as well as of industrial measurement transmitters.
Universal Applicability
The enduring success of MEMS sensors is due to their extremely small dimensions. Additionally, MEMS technology offers the possibility of combining sensors for various measurements into complete micromechatronic subsystems on a single chip. Their compact size, low cost, and processability into highly robust devices enable the measurement of numerous parameters in locations where the use of conventional sensors was previously not practical.
In most cases, MEMS technology is not specifically highlighted, as its use has already become standard in many areas. MEMS sensors play an important role not only in automotive engineering but also in medical technology. There, they are used in wearable and implantable medical devices, such as pacemakers, for the continuous monitoring of vital functions like heart rate or blood sugar levels.
In applications such as mining or the process engineering production of chemicals or pharmaceuticals, MEMS sensors enable real-time monitoring of process-critical and safety-relevant parameters, such as gas concentrations or pressure conditions. This allows for simultaneous optimization of production processes, product quality, and occupational safety.
In mechanical engineering, the simultaneous use of MEMS sensors at numerous points within the same devices, machines, or systems can greatly enhance system efficiency by simultaneously determining the position, path, or relative positions of movable machine parts. For example, software can significantly improve responsiveness to unexpected events, better maintain the quality of the produced product, and ensure functional safety.
SEMINAR TIP
Our manufacturer-independent online seminar offers SMEs and craft businesses, in particular, a practical introduction to the use of cobots. From the theoretical basics and strategic planning of cobot deployments, it moves on to the practical part and the development of individual automation concepts using concrete practical examples.
Here to Stay
At the same time, the measurements collected by MEMS sensors provide the ability to infer the effects of wear or inadequate maintenance from factors such as high-frequency vibrations. Such information enables preventive inspections and interventions by maintenance personnel, as well as adjustments to processing parameters to prevent damage or downtime.
The development of MEMS sensors is far from complete. In addition to further miniaturization, reducing energy consumption, and increasing robustness, the focus is on deeper integration into IIoT networks. For instance, in the future, wireless MEMS sensors with Bluetooth Low Energy or 5G integration will enable energy-efficient, flexible networking of machines for continuous condition monitoring with remarkable density.
The direct integration of MEMS sensors into edge devices with artificial intelligence (AI) not only enables more efficient data processing through preprocessing of sensor signals directly at the point of capture. This not only reduces the costs and uncertainties of data transmission to the cloud for AI analysis but also allows for automatic adjustment of production parameters to subtle changes, raising the efficiency and quality of production processes to an unprecedented level.
MEMS sensors can make cars, machines, and systems much more sensitive and sustainably change the way we move and produce things. They are here to stay.
Christian Reinwald, Head of Product Management & Marketing, Reichelt Elektronik GmbH & Co. KG
:quality(80)/p7i.vogel.de/wcms/45/e4/45e497fad5299ffbb7278c1636a261ba/0129304667v1.jpeg "Screw head forming with heat: The heads of the blanks are heated to over 1,000 °C in the induction stage. (Image:Aachen mechanical engineering)")
:quality(80)/p7i.vogel.de/wcms/bc/df/bcdfa690253179f44dfa43986e35e3d4/0129302450v1.jpeg "The VSC 400 DDS retrofit machine from EMAG at EWS Weigele with tool shuttle for external tool preparation - the basis for reliable hard machining of gears. (Image:Emag Systems)")
:quality(80)/p7i.vogel.de/wcms/f7/85/f785e961fa2a55ecf4380e1a204c79e3/0129432203v1.jpeg "This is the new Artis 300, which completes the Artis range as the third variant. It stands for TIG DC welding up to 300 amps and is designed as an XT variant for all common voltage levels worldwide. (Image:Fronius)")
:quality(80)/p7i.vogel.de/wcms/28/7c/287ccc5ac565d6e6041bebb1e3e073f0/0113143253v1.jpeg "In our China Market Insider, we regularly provide you with relevant information directly from China. (Image:© Eisenhans - stock.adobe.com)")
:quality(80)/p7i.vogel.de/wcms/99/2e/992e57a54c4ddeaafc113de8e56f2b73/0129501004v1.jpeg "Sereact's AI-based control system can process new and unknown items without prior data collection. (Image:Sereact)")
:quality(80)/p7i.vogel.de/wcms/97/3a/973acc83133c28605f855d750523142e/0129492013v1.jpeg "During the opening, Agile One symbolically pressed the start button. (Image:Deutsche Telekom AG / Cindy Albrecht)")
:quality(80)/p7i.vogel.de/wcms/dd/4e/dd4e6ce73e0e700dcc0f0584813ef47f/0128875162v1.jpeg "Thanks to their high precision, robustness and integration capability, Micro-Epsilon's measurement technology solutions are not only suitable for new systems, but also ideal for retrofit applications. (Image:Micro-Epsilon Messtechnik GmbH & Co. KG)")
:quality(80)/p7i.vogel.de/wcms/17/61/1761a0165c23fe007d0a8e62d2a23121/0129467133v1.jpeg "The partnership between Dassault Systèmes and Nvidia aims to make the industry more effective with the help of AI and digital twins. (Picture: ©DC Studio - stock.adobe.com)")
:quality(80)/p7i.vogel.de/wcms/f8/2d/f82d45c2610205e2c0c188968022890d/more-liftoff-power-first-ariane-6-with-four-boosters-launched-4781x2691v1v1.jpeg "The Ariane 6 can be modularly adapted to any mission—either with two or four boosters and a variable payload fairing length. (Image:ESA-M. Pedoussaut)")
:quality(80)/p7i.vogel.de/wcms/9b/e7/9be7c2ceb897aa2bf1ab4eb2198b8b96/roboter-20hand1-1240x698v1v1.jpeg "What if you could 3D print a soft robot with predictable shape-shifting capabilities already built in? (Image:Picture: Harvard University)")
:quality(80)/p7i.vogel.de/wcms/a7/34/a73475e9638e032c32288f53006abab7/newsimage417867-2665x1500v1v1.jpeg "Combination of a model from a scanning electron microscope image (left) with a section of the underlying crystal structure of a studied MXene with precisely controlled surface terminations. (Image:B. Schröder/HZDR)")
:quality(80)/p7i.vogel.de/wcms/d2/1a/d21a9b3e1333f306ffd6421e84f9e3d0/semiconductor-20image-20courtesy-20of-20gelest-3000x1688v1.jpeg "In a new collaboration, IBM will test the performance of Gelest precursor materials for dry resist EUV lithography, generating results that aim to guide Gelest on materials research and speed innovation toward smaller devices. (Source: Gelest)")
:quality(80)/p7i.vogel.de/wcms/ad/72/ad72626a52c9a9332591f457e5afabca/0129497458v1.jpeg "BMW's new Board Member for Development Joachim Post in the new iX3 model. (Image:BMW)")
:quality(80)/p7i.vogel.de/wcms/12/ce/12ce3b8d4062d9e433419e9ada594c34/adobestock-1669527454-marewa-4096x2304v1v1.jpeg "Symbol image (Image:Marewa - stock.adobe.com)")
:quality(80)/p7i.vogel.de/wcms/e8/1f/e81f2bd61d820a0cf982dd3831f273dd/0129511298v1.jpeg "In China, certain functions in new cars will once again be directly accessible via haptic input—without a screen. (Image:BYD)")
:quality(80)/p7i.vogel.de/wcms/0b/02/0b02abc1524e267ae66ad0609ce08b20/0129482073v1.jpeg "The Haval Jolion Pro competes in the compact SUV segment. (Image:GWM)")
:quality(80)/p7i.vogel.de/wcms/68/ec/68ec268edc51a26c4e6e2de7187e8e4f/0129456364v1.jpeg "The storage facilities are being built at three locations in Lithuania. (Image:Nidec Conversion)")
:quality(80)/p7i.vogel.de/wcms/a0/36/a03679debcdda99158f4eaa0d6fbe43d/0129505643v1.jpeg "Arduino App Lab: The current release 0.4.0 brings a number of helpful new features. (Image:Arduino)")
:quality(80)/p7i.vogel.de/wcms/36/c8/36c8b329076027abf5def92031e3028e/0129508876v1.jpeg "Microsoft German headquarters in Munich: As part of the Munich Security Conference, 15 international companies along the entire electronics value chain have formed a tech alliance for digital sovereignty and common trust standards under the leadership of Microsoft and Ericsson. (Image:Microsoft)")
:quality(80)/p7i.vogel.de/wcms/d5/6e/d56e97cb8afab17e93794c1cca214228/0129419457v1.jpeg "China is investing heavily in its domestic semiconductor ecosystem. If you want to be part of it, you should know in advance where which cluster is located and which technology it is driving forward. (Image:Dall-E / AI-generated)")
:fill(fff,0)/images.vogel.de/vogelonline/companyimg/76800/76895/65.jpg "FAULHABER_120mm.jpg ()")
:fill(fff,0)/p7i.vogel.de/companies/67/eb/67eba621ef6ea/logo2.png "logo2 (Wuxi InfiMotion)"){kind=logo}
:quality(80)/p7i.vogel.de/wcms/37/8f/378f38b1ee4ff39af46906a5629da178/0127960109v1.jpeg "The solution from Igus improves process stability and workplace ergonomics in everyday manufacturing. (Image:Igus)")
:quality(80)/p7i.vogel.de/wcms/ef/93/ef9319900ca4ea87d0e426295199ba86/0127982623v1.jpeg "The three-axis acceleration sensor from DIS Sensors is explicitly based on MEMS technology (Image:Reichelt Elektronik)")
:quality(80)/p7i.vogel.de/wcms/a4/2c/a42cd49eaf8b32d1d62a470882257b0e/0127863206v1.jpeg "3-axis vibration measurement: The CMSVT38 is based on modern MEMS sensor technology and reliably measures vibrations in three axes as well as temperature values. (Image:Kübler)")