BeammWave achieves a groundbreaking over-the-air demonstration of distributed digital beamforming
BeammWave, a Swedish company known for its expertise in digital beamforming, has achieved a significant milestone by pioneering the world's first demonstration of distributed digital beamforming. This achievement marks a major leap forward in wireless communication and highlights BeammWave's commitment to technological advancement.
The demonstration has been integrated into the BeammWave Advanced Development Platform (ADP1), offering a solution to the challenges of adopting millimeter wave (mmWave) technology within the 5G ecosystem.
Per-Olof Brandt, the co-founder, and CTO of BeammWave, stated, “We envisioned this concept in 2013 and outlined the design criteria necessary for its realization in high-volume smartphones. Through simulations, testing, and successful system deployment using 5G modulated data, we have brought our vision to life.”
Stefan Svedberg, the CEO of BeammWave, emphasized, “This achievement represents a paradigm shift for 5G networks and holds the potential to shape the utilization of higher frequency spectrum in upcoming generations like 6G. It is poised to unlock new possibilities and drive the emergence of transformative use cases.”
BeammWave's approach to communication solutions for frequencies exceeding 24GHz, along with its patented digital beamforming technology, exemplifies a dedication to delivering unparalleled performance at a lower cost. The company's commitment to innovation has earned it a distinguished position in the industry, with shares listed on the Nasdaq First North Growth Market in Stockholm under the symbol BEAMMW B.
As BeammWave continues to spearhead advancements in wireless communication, their demonstration of distributed digital beamforming stands as a beacon of inspiration and a testament to the possibilities achievable through innovation.
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British researchers develop a machine-learning model to help discover new cryoprotectants for cold storage
The research conducted by scientists from the UK has led to the development of a cutting-edge computational framework that enhances the safe freezing of essential medicines and vaccines. This innovative approach, outlined in the academic journal Nature Communications, marks a significant advancement in cryopreservation, improving the viability and effectiveness of crucial healthcare treatments.
Cryopreservation is essential for storing vaccines, fertility materials, blood donations, and other therapies. It relies on specialized molecules called "cryoprotectants" to maintain the integrity and stability of stored materials during freezing, preserving their therapeutic properties. Without effective cryopreservation methods, treatments may need to be used immediately, limiting their availability for future use.
The research team, led by Professor Gabriele Sosso of the University of Warwick, used machine learning to test hundreds of new molecules as potential cryoprotectants. According to Prof. Sosso, the model's success came from its collaboration with traditional methodologies, demonstrating the value of integrating machine learning with molecular simulations and experimental work.
A significant finding was the identification of a novel molecule capable of inhibiting ice crystal growth during freezing, addressing a longstanding challenge in cryopreservation. While existing cryoprotectants protect cells, they often fail to prevent ice crystal formation, which can compromise the integrity of stored materials.
Dr. Matt Warren, a PhD student involved in the project, highlighted the transformative impact of the machine learning model in predicting cryoprotective activity. He emphasized the potential of machine learning to accelerate scientific research and streamline data analysis.
The team's experiments, including the demonstration of reduced cryoprotectant volumes needed for blood storage and transfusion processes, highlight the practical implications of their findings. These results not only promise to expedite the discovery of new cryoprotectants but also potentially repurpose existing molecules to enhance ice growth inhibition.
Professor Matthew Gibson of the University of Manchester praised the collaboration with Prof. Sosso and emphasized the groundbreaking nature of the findings. He noted that the computational model's identification of active molecules represents a significant leap in understanding cryoprotective properties, showcasing the transformative potential of machine learning in scientific discovery.
This study opens the door to accelerated advancements in cryopreservation research, offering new avenues for the development of efficient cryoprotectants with far-reaching implications across various healthcare sectors.
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Australian researchers build groundbreaking wave scattering simulation software
Can advanced technology soon make invisibility cloaks and other imaginative uses of metamaterials a reality, or is it all just a product of scientific imagination? A new software package from Macquarie University in Sydney, New South Wales, Australia, claims to bring us one step closer to these futuristic possibilities, but not everyone is convinced.
The software, known as TMATSOLVER, boasts the ability to model the intricate interactions of waves with complex materials accurately. Researchers from Macquarie University, in collaboration with various institutions worldwide, are demonstrating the software's ability to simulate multiple wave scattering scenarios.
Lead author Dr. Stuart Hawkins praises the software's capability to model configurations of particles that were previously thought to be unachievable. By using the transition matrix (T-matrix) to describe how objects scatter waves, TMATSOLVER seems to offer a shortcut in designing metamaterials, which are synthetic materials engineered to manipulate waves in unconventional ways.
However, some skeptics question the software's claims of revolutionizing metamaterial design. Dr. Lucy Bennett from an independent research institute remains cautious, stating, "While the concept of TMATSOLVER sounds promising on the surface, the actual implications of its application need to be critically examined. The practicality and real-world impact of such simulations invite scrutiny."
Despite Dr. Hawkins' claims of rapid prototyping and validation of new metamaterial designs, some experts raise concerns about the software's effectiveness in practical settings. Dr. Bennett notes, "The gap between simulation and real-world implementation remains a significant challenge. The 'easy-to-use' tagline of TMATSOLVER may oversimplify the complexities of metamaterial engineering."
Metamaterials, with applications ranging from super-lenses to invisibility cloaks, have sparked the imagination of scientists and engineers. However, as the buzz around TMATSOLVER grows, so do the voices of skepticism, calling for a more thorough assessment of its true potential.
As the debate over the impact of TMATSOLVER continues, only time will tell whether this software signals a new era of metamaterial innovation or turns out to be a passing trend.
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