Modular precision measurement technology for universities
We offer the ideal measuring devices for universities. Both for teaching and for experiments in specific research - our measurement technology supports universities in a variety of ways.
Our modular LTT24 precision measuring device is ideal for use in research and development at universities thanks to the variable combination of numbers of inputs, selectable options and sensors. Whatever the requirements of the laboratory or experiment, the LTT24 can be tailored specifically to the respective measurement task.
In addition, we also offer the LTTsmart power analyzer for electrical power measurement (including high-voltage applications).
Our latest development, the compact AD converter module system ADCstamp, offers a convenient solution for setting up high-performance data acquisition systems (DAQ). The use of one ADCstamp module per measurement channel in an FPGA-based system enables the rapid implementation of high-precision measurement channels with little integration effort. Especially for research projects and teaching, this enables (prospective) system developers to concentrate on higher-value tasks - without having to deal in detail with the demanding analog and digital design of the measurement channels.
We look forward to making a contribution to progress in research and development right now. Feel free to contact us and we will advise you individually to find the ideal solution for your measuring task together. Of course, we also offer the possibility of a free demo appointment.
Examples of applications for the LTT24 measuring device in research:
LTT precision measurement technology has already made a significant contribution in many areas of research. If you are wondering whether our measurement technology could also play a role in your research, here are a few examples of how the LTT24 is used:
- Material testing on granite during blasting tests: Chi, L. Y. et al. (2019): Measurement of shock pressure and shock-wave attenuation near a blast hole in rock, International Journal of Impact Engineering, 125, 27-38. Link: ScienceDirect
- Sensor testing during car crashes: Sequeira, G. J. et al. (2019): Avalidation sensor based on carbon-fiber-reinforced plastic for early activation of automotive occupant restraint systems, Journal of Sensors and Sensor Systems, 8, 19-35. Link: Copernicus
- Material tests under ballistic loads: Zockowski, P. et al. (2022): Experimental Study on Failure Mechanisms of Novel Visco-Hyperelastic Material Target Under Ballistic Impact Conditions, Structural Integrity (Conference), 24, 323-329. Link: Springer Nature
- Impedance behavior of an electrical coil with interchangeable core: Tareq, A., Kertzscher, J. (2018): Fractional-Order Impedance Modeling and Parameter Identification of an Electrical Coil with Interchangeable Core, Proceedings of International Conference on Fractional Differentiation and its Applications (ICFDA). Link: SSRN
- Optimization of the noise behavior of planar Hall magnetoresistance sensors with a multiring structure: Schmidtpeter, J. et al. (2024): Exchange-Biased Multiring Planar Hall Magnetoresistive Sensors With Nanotesla Resolution in Nonshielded Environments, IEEE MAGNETICS LETTERS, 15, 1-5. Link: IEEE Xplore
- Effects of high strain rates and varying moisture contents on the dynamic compression behavior and strength parameters of silty sand under uniaxial conditions: Chmielewski, R., et al. (2021): Experimental investigation of dynamic behavior of silty sand, Archives of Civil Engineering, 481-498. Link: journals.pan
- Effect of different thicknesses, fiber arrangements, and fabric structures on the energy absorption capacity and failure mechanisms of circular carbon/epoxy composite tubes under both slow (quasi-static) and sudden (dynamic) pressure loads: Liu, X., et al. (2019): Experimental investigation of energy absorption behavior of circular carbon/epoxy composite tubes under quasi-static and dynamic crush loading, Composite Structures, 227, 111266. Link: ScienceDirect
Musicological universities
Our measurement technology is not only used in laboratory experiments. Musicological universities can also benefit from the high precision and reliability of our measuring devices, e.g. for:
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