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Modules provide alternative to RF SoCs
Modules provide alternative to RF SoCs Module technology, including system-in-a-package (SiP) and multi-chip modules (MCMs), is creating attractive alternatives to the system-on-a-chip (SoC) design methodology for systems that require radio frequency (RF) and analog functionality. Low-temperature co-fired ceramic (LTCC) and other packaging methods are advantageous because they can integrate multiple best-in-class technology components, including integrated circuits (ICs) and surface mount devices (SMDs), while enabling embedded passives and interconnect circuitry to be sandwiched between the substrate layers. The module platform is a viable SoC alternative in terms of time-to-market, cost, product size, and performance. When compared to complementary metal oxide semiconductor (CMOS) ICs, the economics of the module platform can provide significant financial improvements. Unlike earlier module technology, LTCC has matured to a point that seven out of 10 Bluetooth solutions now use the LT CC module platform. Additionally, cell phone handsets, automotive and consumer electronics, and medical products are currently manufactured using module technology because of its many inherent advantages. The cell phone baseband module in Figure 1 is an excellent example of a wireless handset application. Despite the many advantages, continued growth of the module platform market will require significant improvements and committed support from electronic design automation (EDA) companies.  Figure 1 -- Cellphone baseband module Advantages of module platforms include:
 Figure 2 -- MCM miniaturization A primary roadblock to module platform design is the integration and interoperability of simulation and layout tools. Last year's RFIC conference in Seattle, and a subsequent EE Times article, outlined the need for EDA companies to actively support a module platform design flow. Module design houses and manufacturing companies are experiencing the pain of inadequate EDA tools and, without resolution, this will stifle the growth and development of this technology. Module design requires an integrated and interactive design environment that can handle the physical layout of ICs and PCBs to ensure productive and efficient use of design resources. A key requirement for the module platform design technology is the ability to interactively design components in multiple descriptions simultaneously, and to understand upfront the impact of interconnect. Because RF and high-frequency design requires a tightly coupled interaction between physical descriptions and electrical models, the ideal design suite is built upon an object-orie nted database that enables design elements to be described, visualized, simulated, and analyzed using electrical, physical, and logical views. For example, Applied Wave Research's Microwave Office software provides a single design environment where the RF engineer can create, modify, simulate, and analyze a spiral inductor using a physical layout and an electrical model based on electromagnetic simulation. AWR has also created process design kits (PDKs) for leading LTCC foundries. These PDKs have been validated on designs such as the complete receiver in Figure 4. Embedded passives (R, C, L) have been created that enable the designer to create continuous configurations of length, width, spacing, and turns (spiral inductor). This design includes multiple ICs from various process technologies, discrete SMDs, and embedded passives. The module platform provides a compel ling alternative to the current SoC trend of single IC integration and is verified by the successful design and layout of complex RF MCMs. Mark Rencher is president of Applied Wave Research. |
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