Electronics

Latest Innovations
NetDIMM The emergence of datacenters as single computer entities has made latency a critical consideration in designing datacenter networks. PCIe interconnect is known to be a... Read More The emergence of datacenters as single computer entities has made latency a critical consideration in designing datacenter networks. PCIe interconnect is known to be a latency bottleneck in communication networks as its overhead can contribute to up to 90% of the overall communication latency. PCIe is a standard motherboard interface, sending a packet over a conventional NIC requiring several PCIe and memory channel transactions. This data movement in the network software stacks consumes thousands of processor cycles, which ultimately prevent ultra-low latency networking. Researchers eliminate NIC-PCIe transactions and instead use the local memory channels between the memory and NIC, resulting in reduced latency and improved data center computer performance (figure 1). This finding is the basis for NetDIMM, which is a method for integrating a network interface chip with the memory module of a computer. Figure 1: State of the art network interface architectures vs. NetDIMM On average, NetDIMM improves per packet latency by 49.9% compared with a baseline network deploying PCIe NICs (figure 2). The NetDIMM architecture is located in the memory module and does not require any change to the processor architecture or memory subsystem. Figure 2: One-way network latency breakdown for packets of various sizes when using a PCIe NIC (left), an integrated NIC (middle), and NetDIMM (left). X-axis is not drawn to scale. Most recently, NetDIMM was presented at the 52nd IEEE/ACM International Symposium on Microarchitecture in Columbus, Ohio. The conference publication can be accessed here.
Plasma Photonic Crystals Device with Plasmonic Resonances in the Microwave, Millimeter Wave, and Terahertz Spectral Regions Dr. Eden at the University of Illinois has developed a 3D microplasma photonic crystal which provides the ability to introduce or completely suppress attenuation... Read More Dr. Eden at the University of Illinois has developed a 3D microplasma photonic crystal which provides the ability to introduce or completely suppress attenuation resonances at will, in the microwave, millimeter wave, and terahertz spectral regions, while minimizing insertion loss. This complex 3D photonic crystal is comprised of a 3D-printed polymer scaffold, and free-standing arrays of polyimide capillaries. Since the capillaries are suspended in free space on the scaffold, electromagnetic structures can be placed on or around the microtubes. One example of this involves depositing metal films onto each capillary with precise periodicity. In this way, each pair of neighboring metal film rings in the 3D array are effectively coupled and constitute a capacitor, creating extremely versatile, and tunable crystal performance. Applications Microwave, millimiter-wave, terahertz communications, DoD/military (optical cloaking, electronic warfare)
Application Level Hardware Tracing for Scaling Post-Silicon Debug Dr. Vasudevan from the University of IL has developed an advanced algorithm for optimizing design-for-debug hardware. This algorithm takes advantage of high level... Read More Dr. Vasudevan from the University of IL has developed an advanced algorithm for optimizing design-for-debug hardware. This algorithm takes advantage of high level abstraction to enable accurate bug localization, eliminating almost 90% of possible root causes in tests using an industrial SoC. This technology, which is broadly scalable versus existing methods, addresses a great need in the field of Electronic Design Automation by decreasing the cost and shortening the timescale of chip debugging, accelerating time-to-market and streamlining the post-silicon validation phase. Application: Incorporation into chip design and verification software Publication: Pal, D.; Sharma, A.; Ray, S.; de Paula, F. M.; and Vasudevan, S. In Proceedings of the 55th Annual Design Automation Conference, DAC 2018, San Francisco, CA, USA, June 24-29, 2018, pages 92:1–92:6, 2018.
Single-chip Neural Probe with High Temporal Resolution Dr. Yurii Vlasov from the University of Illinois has developed a single-chip neural nanodialysis probe that can sample in vivo brain chemicals, store them, and then... Read More Dr. Yurii Vlasov from the University of Illinois has developed a single-chip neural nanodialysis probe that can sample in vivo brain chemicals, store them, and then directly deploy them for analysis, all while maintaining high temporal resolution. This device uses reversible inlets-outlets and embedded ionization ports to both sample in vivo brain chemicals and deploy them, without need for intermediate storage. This risks less contamination or Taylor dispersion than other methods, and reduces the need for bulky peripherals. Application This can be used for collecting and analyzing in-vivo biochemical concentrations in the brain. Benefits This is a single chip silicon neural probe that can sample live chemicals, store them, and then directly deploy them for analysis. Other neural probes cannot store and deploy these chemical samples, which reduces the temporal resolution of the samples.
5G Acoustic Filters Dr. Songbin Gong from the University of Illinois has developed a suite of technologies for the design strategy and method of fabricating acoustic front-end filters at various frequencies,... Read More Dr. Songbin Gong from the University of Illinois has developed a suite of technologies for the design strategy and method of fabricating acoustic front-end filters at various frequencies, including frequencies > 6 GHz. These acoustic front-end filters demonstrate high electromechanical coupling, high fractional bandwidths, as well as high quality factors. This is achieved through a combination of materials selection, resonator design, and filter design. This technology: Increases the frequency range and the fractional bandwidth of acoustic filters Enables the future generations of wireless communication Allows access to frequency bands above 6 GHz and provides the high FBW required for 5G communications
Ultrasoft Slip-mediated Bending in Few-layer Graphene This technology leverages the bending stiffness and super lubricity of few-layer materials to create ultra-flexible 2D materials with tunable electronic properties.... Read More This technology leverages the bending stiffness and super lubricity of few-layer materials to create ultra-flexible 2D materials with tunable electronic properties. Applications include MEMS actuators and flexible/stretchable electronics, as well as the miniaturization of a variety of macroscale actuator devices.
High Resolution Distributed Sensor Inventors from the University of Illinois have developed novel phase-separated optical fibers for use in a distributed sensor. These phase-separated optical fibers have... Read More Inventors from the University of Illinois have developed novel phase-separated optical fibers for use in a distributed sensor. These phase-separated optical fibers have high loss (0.05 to 5 dB/m @ 1550 nm) when compared with conventional optical fibers, and the loss dominated by Rayleigh scattering. Moreover, these phase separated fibers are produced through a molten core method (MCM) which makes the cost of production relatively low when compared with conventional fibers. When employed in a Rayleigh based distributed sensor these phase-separated optical fibers provide short-range sensitivity that is orders of magnitude greater than conventional fibers.
Energy Efficient Nanoscale Capacitor Dr. Alexey Bezryadin, with his research group, has developed a dielectric capacitor that provides 200 J/g of storage density. By injecting and trapping charges within a... Read More Dr. Alexey Bezryadin, with his research group, has developed a dielectric capacitor that provides 200 J/g of storage density. By injecting and trapping charges within a thin dielectric layer, a Coulomb barrier is created that prevents leakage currents that cause capacitors to discharge more quickly. Initial applications for the technology are in cold electronics, which could include quantum computing, space technologies, infrared cameras, or MRI machines.
Method To Produce Nanoscale 3D Porous Silicon Patterns and Applications This method of forming a nanoscale three-dimensional pattern in a porous semiconductor includes providing a film comprising a semiconductor material and defining a... Read More This method of forming a nanoscale three-dimensional pattern in a porous semiconductor includes providing a film comprising a semiconductor material and defining a nanoscale metal pattern on the film, where the metal pattern has at least one lateral dimension of about 100 nm or less in size. Semiconductor material is removed from below the nanoscale metal pattern to create trenches in the film having a depth-to-width aspect ratio of at least about 10:1, while pores are formed in remaining portions of the film adjacent to the trenches. The method can be extended to form self-integrated porous low-k dielectric insulators with copper interconnects.
Improved Method for Fabricating a S-RuM Inductor with High Q This is a new method for fabricating a self-rolled-up membrane (S-RuM) membrane. The invention allows for the fabrication of high-quality-factor milliTesla- and Tesla-... Read More This is a new method for fabricating a self-rolled-up membrane (S-RuM) membrane. The invention allows for the fabrication of high-quality-factor milliTesla- and Tesla-level inductors for high density circuit applications and allows for the precise tuning of the inductor performance by varying the space between subsequent turns (coils), which affects the thickness of the conducting layers within the inductor. Importantly, this method provides tunable three-dimensional inductors with a reduced footprint when compared with conventional planar inductors.