Test results between 10 and 100 times faster than traditional near-field antenna measurement systems.
The time-to-market demands and deployment milestones of the NewSpace sector for LEO satellites has given rise to the SG EVO, a new multi-probe, spherical near-field antenna measurement and OTA testing solution for satellite antenna systems.
The SG Evo is featured in the 2021 June edition of the Microwave Journal. Read all about it!
The Microwave Journal, the leading publication and web source for information about RF and Microwave technology, introduces MVG’s AeroLab as a product feature in their September Military and Aerospace supplement.
Check out the story on MWJ.
Bringing MVG multi-probe microwave testing technology to the aircraft radome testing market, AeroLab was designed specifically for testing aircraft nose radomes in the repair and test environment.
5G NR expands into higher frequencies and uses new technologies that increase complexity in the way signals are built, transmitted and processed compared to 4G. As the standard continues to evolve, more new features will be added so testing needs to be flexible and ready to adapt to the higher mmWave frequencies with wider bandwidths, denser waveforms and a growing number of test cases.
This latest eBook of Microwave Journal starts out with a couple of general articles about 5G testing challenges and a 5G NR standards overview. One article provides an overview of the various test methods including the advantages and disadvantages of the methods. Then it summarizes some of the solutions available from 9 leading test and measurement companies in this field, including MVG's solutions. You will be able to read the latest case study on how MVG's mmWave OTA test system provides proof of concept for measuring 5G beamforming.
Read this eBook to learn more about the challenges and solutions for 5G OTA testing!
The success behind the large diffusion of microsatellites in the space field is due mainly to fast mission implementation and to the low overall costs, allowing the access to space also for SMEs and Research Institutes with small budgets.
The objective of the STRAIM (Sistema di Test Rapido per Antenne Integrate in Microsatelliti - Rapid Test System for Antennas Integrated on Microsatellites) project is to develop a testing methodology with strong time and cost reduction for microsatellite Antenna Integration and Test Verification to further contribute to the cost effective use of microsatellites.
Three prototypes will be developed in this activity, regarding respectively the equivalent currents technique (INSIGHT), the raytracing method (SATSIM) and a system for automatic image acquisition.
The project will be developed by MVG Italy and Step Over srl.
The project is cofounded by the European Union (CE - Comunità Europea) for an amount of k€ 238.
AMTA, the Antenna Measurement Technique Association, is dedicated to the development, application, and dissemination of advanced antenna, radar signature, and related measurement technologies. This international organization has influenced the industry with innovation and insight in the field since 1979. Its highly anticipated symposium brings together members from around the world to share technological advances. The non-profit organization thrives as a result of volunteer efforts from devoted members. Recognition to those who prove themselves to be fully dedicated not only to AMTA, but to advancements in technology in the field, naturally follows.
MVG has been involved in AMTA for more than 34 years! Several MVG employees have been dedicated to AMTA as board members and more. We are proud and pleased to announce that 3 of our team were awarded at this year’s annual AMTA Symposium.
Top of the list, Lars Foged, MVG Scientific Director, earned the AMTA Distinguished Achievement Award for his outstanding pioneering and contributions to the practice of antenna design, analysis and measurement. This is the most honorable of all AMTA awards.
Then, John Estrada received his plaque of recognition for outstanding service to AMTA. John has been an active member for more than 25 years. He chaired and hosted AMTA 2010 while Managing Director of Satimo USA, was a member of the board from 2014 to 2016, as meeting coordinator and Vice President, and continues to serve as he takes part in the organization committee for AMTA 2018 in Williamsburg.
Finally, Ed Szpindor was awarded recognition as a Senior Member of AMTA. He has been a member for more than 15 years and was awarded for his continuous contributions.
Congratulations Lars, John and Ed for these accomplishments. We are also grateful for your contributions, time and energy at MVG!
On the occasion of the ESoA Summer courses which took place in China in August, Microwave Journal interviewed exclusively Lars Foged on antenna test and measurement technologies as well as MVG's competitve advantages.
Take a look at some very challenging questions the journalist asked:
"What technical problems are antenna test and measurement engineers facing today?"
"How do the emerging antenna technologies and applications such as antennas for 5G base stations and handsets, IoT devices, massive MIMO, commercial phased-arrays, 3D printing, metamaterials, etc., affect the methods and techniques of antenna test and measurement?"
"Which standards for antenna test and measurement are in development now? What’s the role of MVG in the international antenna test and measurement standards process?"
"Can MVG’s existing antenna test products and solutions meet all the testing requirements of all existing antennas? Whatever the frequency, power, size and form factor of an antenna are, and what scenarios are: on-site, in a production line or in a laboratory."
Check out Lars Foged's brillant answers and read the whole interview in English by clicking here!
Read the interview in Chinese by clicking here!
MVG’s Scientific Director, Lars Foged, has been nominated the 2016 Chair of the Industrial Initiatives Committee of the IEEE Antenna and Propagation Society (AP-S).
The IEEE AP-S brings together technological experts in antennas, including analysis, design, development, measurement, and testing; radiation, propagation, and the interaction of electromagnetic waves with discrete and continuous media; and applications and systems pertinent to antennas, propagation, and sensing.
The AP-S has a number of standing committees organized yearly. The main charter for the Industry Initiatives Committee is to represent the industrial community and to promote its interests in future AP-S activities. Lars will be contributing to activities that aim to gain recognition of the IEEE AP-S in the Industry, and to identify industry members for future Fellow and technical field awards.
MVG is proud to have been part of a European project to develop a new antenna for the tracking of oceangoing vessels from space via Satellite.
A VHF array antenna was designed for mini-satellite platforms in Low Earth Orbit. In partnership with CGS, who piloted the project, MVG Italy developed the electromagnetic design, and manufactured and tested the array antenna.
News from ESA:
What might look like an abstract artwork is actually a novel antenna, small enough for a minisatellite, to track global ship traffic from orbit.
Commercial vessels are mandated to transmit Automatic Identification System (AIS) signals, which are used to track maritime traffic – the oceangoing equivalent of air traffic control. The system relies on VHF radio signals with a horizontal range of just 40 nautical miles (74 km), useful within coastal zones and on a ship-to-ship basis, but leaving open ocean traffic largely uncovered.
However, in 2010 ESA fitted an experimental antenna to Europe’s Columbus module of the International Space Station, demonstrating for the first time that AIS signals could also be detected from up in orbit, opening up the prospect of global ship tracking from space.
“Based on our testing, this new prototype designs offers a four-fold increase in ship detection performance,” explains ESA antenna specialist Nelson Fonseca, overseeing the project.
“The AIS detection system on Columbus employs a low-gain ‘whip’ antenna, receiving signals within a very broad beam, with corresponding potential for signal overlap and interference.
“This antenna design combines higher-gain with a more reduced footprint, allowing more of a focus on regions of highest interest, and can also discriminate between polarisations, increasing the likelihood of detection for any individual AIS signal within the antenna field of view.”
In addition, clever engineering has shrunk the overall antenna size to a size where up to five could be hosted on a single cubic-metre minisatellite.
“Despite its name, VHF is quite a low wavelength in space terms, implying a bulky antenna of about 1 m across and half-a-metre thick to operate ideally at that frequency,” Nelson adds.
“But the patterned square-shaped structure on the underlying face of our antenna changes the signal behaviour, enabling us to shrink the design to 50 cm width and 3 cm thickness – making it suitable for hosting on a smaller platform.”
The antenna was developed through ESA’s ARTES Advanced Research in Telecommunications Systems – Advanced Technology programme with Italian companies CGS as prime contractor and MVG as subcontractor in charge of the electrical design.
“CGS and MVG are highly interested in moving forward with the optimisation and environmental qualification of this outstanding antenna element,” explains Andrea Di Cintio, managing the project at CGS. “The next step will be to identify a specific mission and then optimise the design and qualification accordingly.”
“Significant reduction of antenna dimensions and weight without compromising electrical performance was challenging,” adds Andrea Giacomini, lead antenna designer at MVG. “It required a radical change in the design and validation approach. We are proud to have been involved.”
Active Antenna System (AAS) technology is receiving increased attention as a component for upcoming 5G cellular networks. These networks will have flexible radiation patterns that are capable of adapting to changing conditions. In order to fully characterize AAS’ in the 3D space, a new approach to active antenna measurement will be required. This article takes a look at new ways to achieve quick and accurate AAS characterization.