Key Takeaways
  • Texas Engineers have solved key issues related to ラーメンベット 出金 銀行 for computing that can both store and process information at the same time, using magnetism;
  • Found a way to speed up repetitive tasks, similar to muscle memory, that is adaptable to the repetitiveness of the dataset;
  • And found that these ラーメンベット 出金 銀行 are capable of standing up to high levels of radiation.
  • These discoveries represent important steps in the quest to make computers think more like human brains, aka neuromorphic ラーメンベット 出金 銀行.

We are in the midst of a ラーメンベット 出金 銀行 revolution, as cutting-edge research is fundamentally re-imagining how computers think and process information to enable and improve next-generation applications. This computational re-programming brings with it a litany of ongoing challenges for engineers and scientists.

Researchers at The University of Texas at Austin are studying a magnetic ラーメンベット 出金 銀行 that breaks down key barriers for how information is stored and processed as part of the quest to make computers think more like humans. Jean Anne Incorvia, an assistant professor in the ラーメンベット 禁止ゲーム's Department of Electrical and Computer Engineering, recently published a trio of papers seeking to solve challenges facing these new ラーメンベット 出金 銀行 paradigms.

“There are a lot of new physics and materials that we are always discovering, and how you translate those into applications could give us the ability to do a whole new breadth of things in ラーメンベット 出金 銀行,” Incorvia said.

Incorvia noted that we are beginning to reach the limits of how small and powerful silicon chips can be. This has initiated a race to develop ラーメンベット 出金 銀行 building blocks for computers that can think like human brains to accomplish complex tasks.

The push toward neuromorphic computing can enable dynamic applications that require processing ラーメンベット 出金 銀行 able to shift and adapt to changing environments on the fly. Some examples include circuits for self-driving vehicles, pattern and image recognition systems and Internet of Things ラーメンベット 出金 銀行.

"Why stick with silicon when we can create ラーメンベット 出金 銀行 with bio-inspired behaviors that could be used for furthering and expanding what computing can do?" Incorvia said.

diagram of neuromorphic ラーメンベット 出金 銀行 device

A New Device to Solve Next-Gen ラーメンベット 出金 銀行 Issues

In a new paper, Incorvia and her students solved challenges related to a new in-memory computing device. These magnetic ラーメンベット 出金 銀行 can simultaneously store information and process it, providing a huge speed and energy improvement over traditional computing ラーメンベット 出金 銀行.

The ラーメンベット 出金 銀行 device, called a domain wall-magnetic tunnel junctionand described in Applied Physics Letters, was a fabrication triumph. It was built in such a way that it achieves a remarkably high on/off ratio, given its more complex structure compared to traditional magnetic memories, which is important for translating information stored in the magnetic component to ones and zeros for computing purposes. The higher the on/off ratio, called the tunnel magnetoresistance, the easier it is to distinguish the ones and zeros. A low on/off ratio means the ones and zeros start to blur together, making it harder to compute with the ラーメンベット 出金 銀行.

Incorvia says groups at Intel and IMEC have made similar ラーメンベット 出金 銀行 with an on/off ratio of about 15%. An MIT group made one with a 40% ratio. Incorvia's device boasts an on/off ratio between 170% and 200%.

The device is made of a stack of nano-meter-thin layers, grown in collaboration with Applied Materials. Patterning the layers into nanostructured ラーメンベット 出金 銀行 without damaging them was key to the on/off achievement, a process led by Thomas Leonard, a graduate student in Incorvia's lab.

The ラーメンベット 出金 銀行 described in the paper represent the fifth iteration. Now Leonard is on the ninth version. The fabrication was done using UT Austin’s Microelectronics ラーメンベット 出金 銀行 Center, a world-class clean room facility for processing nano-ラーメンベット 出金 銀行, and the research was supported by Sandia National Laboratories’ Laboratory Directed Research and Development (LDRD) Program.

The new ラーメンベット 出金 銀行 use a new method of controlling the magnetization with applied current, called spin orbit torque, which enables the ラーメンベット 出金 銀行 to switch at lower energies and more reliably. With the combination of high tunnel magnetoresistance and reliable switching behavior, they were able to show, for the first time, that the domain wall-magnetic tunnel junctions can repeatably operate in a circuit. This opens up the ability to build in-memory computing circuits with magnetism.

Computers With Muscle Memory

We all do things every day that feel like second nature. These repetitive actions become so simple because the brain and body are used to performing them.

Incorvia and her team have applied ラーメンベット 出金 銀行 principle of muscle memory to their magnetic device by showing it has an "edgy-relaxed" behavioral capability. As described in IEEE Magnetics Letters, ラーメンベット 出金 銀行 allows the neurons to fire faster when doing a repetitive task, speeding up the processing abilities.

Incorvia’s team showed using device and circuit modeling that the concept comes in handy when doing tasks like image recognition. The magnetic ラーメンベット 出金 銀行 could recognize similar types of images at a faster rate, while not taking up as much computing resources, leaving plenty of bandwidth for harder tasks. The method could be useful in a number of other applications, including speech recognition where there are many frequently repeated sounds and phrases.

The researchers showed the ラーメンベット 出金 銀行 are adaptable. Depending on the repetitiveness of the dataset, the “edgy-relaxed” behavior can be altered to most efficiently process the data. This is a step closer to using new hardware for context-aware computing. This work was supported by a National Science Foundation CAREER award.

ラーメンベット 出金 銀行 Resistant

Magnetic ラーメンベット 出金 銀行 like the ones Incorvia's team creates tend to hold up well under high-radiation conditions, in a way silicon chips don't. This is because radiation can create electrical charges that affect electrical-based ラーメンベット 出金 銀行 much more than magnetic-based ラーメンベット 出金 銀行. This is particularly relevant to space applications, where high levels of radiation are a challenge.

In the third paper, published in IEEE Transactions on Nuclear Science, the team tested the thin film stack detailed in Applied Science Letters for resistance to radiation. The researchers worried that the structural differences between the new device and other magnetic ラーメンベット 出金 銀行 would nullify its radiation resistance. That wasn't the case, and the new device stood up well to radiation exposure.

The team applied high doses of ラーメンベット 出金 銀行 and used resources at the Texas Materials Institute to analyze what happens when breakdown does occur. They found that high levels of radiation affect the nanometer-thick layers at the bottom of the multi-layer stack more than layers at the top of the stack. This finding will help inform design considerations when adapting these magnetic ラーメンベット 出金 銀行 to high radiation environments.

“Using nanomagnetism in ラーメンベット 出金 銀行 combines cutting-edge ideas in electrical engineering, computer engineering, physics, materials science and neuroscience,” Incorvia said. “We are just starting out on what can be done, and these results provide some clear directions on where to go next.”