1,644 research outputs found
Air-gap C4 Fluidic I/O Interconnects And Methods Of Fabricating Same
An exemplary embodiment of the present invention provides a chip for use in fabricating a three-dimensional integrated circuit, the chip comprising a wafer, one or more metallic-filled, electrical vias, and one or more hollow, fluidic vias. The wafer can comprise a first surface and a second surface. The one or more metallic-filled, electrical vias can extend through the wafer. Each electrical via can be in electrical communication with an electrical interconnect proximate the first surface, providing electrical communication between chips in the integrated circuit. The one or more hollow, fluidic vias can extend through the wafer. Each fluidic via can be in fluid communication with a fluidic interconnect, providing fluid communication between adjacent chips in the integrated circuit. Each fluidic interconnect can comprise a first end proximate the first surface, a second end, and a cap proximate the second end, defining an air-filled space within the fluidic interconnect.Georgia Tech Research Corporatio
3-D ICS With Microfluidic Interconnects And Methods Of Constructing Same
Three dimensional integrated circuits with microfluidic interconnects and methods of constructing same are provided. According to some embodiments, and microfluidic integrated circuit system can comprise a plurality of semiconductor die wafers each having a top and bottom exterior surface. The semiconductor die wafers can form a stack of die wafers. The die wafers can comprise one or more channels formed through the die wafers. The channels can extend generally between top and bottom exterior surfaces of the semiconductor die wafers. A plurality of micro-pipes can be disposed between adjacent semiconductor die wafers in the stack. The micro-pipes can enable the channels to be in fluid communication with each other. A barrier layer can be disposed within at least one of the channels and the micro-pipes. The barrier layer can be adapted to prevent a coolant flowing through the at least one of the channels and the micro-pipes from leeching into the channels and micro-pipes. Other embodiments are also claimed and described.Georgia Tech Research Corporatio
Exploring the design space for 3D clustered architectures
Journal Article3D die-stacked chips are emerging as intriguing prospects for the future because of their ability to reduce on-chip wire delays and power consumption. However, they will likely cause an increase in chip operating temperature, which is already a major bottleneck in modern microprocessor design. We believe that 3D will provide the highest performance benefit for high-ILP cores, where wire delays for 2D designs can be substantial. A clustered microarchitecture is an example of a complexity-effective implementation of a high-ILP core. In this paper, we consider 3D organizations of a single-threaded clustered microarchitecture to understand how floorplanning impacts performance and temperature. We first show that delays between the data cache and ALUs are most critical to performance. We then present a novel 3D layout that provides the best balance between temperature and performance. The best-performing 3D layout has 12% higher performance than the best-performing 2D layout
Understanding the impact of 3D stacked layouts on ILP
Journal Article3D die-stacked chips can alleviate the penalties imposed by long wires within micro-processor circuits. Many recent studies have attempted to partition each microprocessor structure across three dimensions to reduce their access times. In this paper, we implement each microprocessor structure on a single 2D die and leverage 3D to reduce the lengths of wires that communicate data between microprocessor structures within a single core. We begin with a criticality analysis of inter-structure wire delays and show that for most tra- ditional simple superscalar cores, 2D floorplans are already very efficient at minimizing critical wire delays. For an aggressive wire-constrained clustered superscalar architecture, an exploration of the design space reveals that 3D can yield higher benefit. However, this benefit may be negated by the higher power density and temperature entailed by 3D integration. Overall, we report a negative result and argue against leveraging 3D for higher ILP
Temperature Evaluation of NoC Architectures and Dynamically Reconfigurable NoC
Advancements in the field of chip fabrication led to the integration of a large number of transistors in a small area, giving rise to the multi–core processor era. Massive multi–core processors facilitate innovation and research in the field of healthcare, defense, entertainment, meteorology and many others. Reduction in chip area and increase in the number of on–chip cores is accompanied by power and temperature issues. In high performance multi–core chips, power and heat are predominant constraints. High performance massive multicore systems suffer from thermal hotspots, exacerbating the problem of reliability in deep submicron technologies. High power consumption not only increases the chip temperature but also jeopardizes the integrity of the system. Hence, there is a need to explore holistic power and thermal optimization and management strategies for massive on–chip multi–core environments.
In multi–core environments, the communication fabric plays a major role in deciding the efficiency of the system. In multi–core processor chips this communication infrastructure is predominantly a Network–on–Chip (NoC). Tradition NoC designs incorporate planar interconnects as a result these NoCs have long, multi–hop wireline links for data exchange. Due to the presence of multi–hop planar links such NoC architectures fall prey to high latency, significant power dissipation and temperature hotspots. Networks inspired from nature are envisioned as an enabling technology to achieve highly efficient and low power NoC designs. Adopting wireless technology in such architectures enhance their performance. Placement of wireless interconnects (WIs) alters the behavior of the network and hence a random deployment of WIs may not result in a thermally optimal solution. In such scenarios, the WIs being highly efficient would attract high traffic densities resulting in thermal hotspots. Hence, the location and utilization of the wireless links is a key factor in obtaining a thermal optimal highly efficient Network–on–chip.
Optimization of the NoC framework alone is incapable of addressing the effects due to the runtime dynamics of the system. Minimal paths solely optimized for performance in the network may lead to excessive utilization of certain NoC components leading to thermal hotspots. Hence, architectural innovation in conjunction with suitable power and thermal management strategies is the key for designing high performance and energy–efficient multicore systems. This work contributes at exploring various wired and wireless NoC architectures that achieve best trade–offs between temperature, performance and energy–efficiency. It further proposes an adaptive routing scheme which factors in the thermal profile of the chip. The proposed routing mechanism dynamically reacts to the thermal profile of the chip and takes measures to avoid thermal hotspots, achieving a thermally efficient dynamically reconfigurable network on chip architecture
Photonic packaging: transforming silicon photonic integrated circuits into photonic devices
Dedicated multi-project wafer (MPW) runs for photonic integrated circuits (PICs) from Si foundries mean that researchers and small-to-medium enterprises (SMEs) can now afford to design and fabricate Si photonic chips. While these bare Si-PICs are adequate for testing new device and circuit designs on a probe-station, they cannot be developed into prototype devices, or tested outside of the laboratory, without first packaging them into a durable module. Photonic packaging of PICs is significantly more challenging, and currently orders of magnitude more expensive, than electronic packaging, because it calls for robust micron-level alignment of optical components, precise real-time temperature control, and often a high degree of vertical and horizontal electrical integration. Photonic packaging is perhaps the most significant bottleneck in the development of commercially relevant integrated photonic devices. This article describes how the key optical, electrical, and thermal requirements of Si-PIC packaging can be met, and what further progress is needed before industrial scale-up can be achieved
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