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Below are the steps that are required in a custom IC design flow:

• Architectural Design. Here, the required functionality of the IC or the particular block is specified. What functions must the IC or block deliver? What is the required speed and power consumption? What is the target cost?  The answers to these questions will inform subsequent choices for the specific technology that will be used to implement the device. At this stage, ¡°what¡± is required is most important.  ¡°How¡± it will be implemented is still not well defined.
• Logic / Circuit Design. Here, macro-level building blocks are interconnected to implement the required functionality of the IC or block. The collection of devices is simulated to verify the functionality of the design. Either a digital logic simulator or an analog circuit simulator will be used, depending on the level of simulation detail that is required. During this step, ¡°how¡± the chip or block will be implemented begins to be defined.
• Physical Design. During this step, the actual layout of the interconnected shapes that implement all the required circuit elements on the silicon wafer are created. The process begins with a chip ¡°floorplan,¡±which defines where each of the primary functions of the chip will be located and where the primary input and output ports of the design will be located. If a smaller building block is being designed, this step may be skipped. Next, a custom layout editor is used to implement the physical layout of the actual shapes that will create the circuit on the silicon wafer. Advanced layout editors will provide real-time feedback to the designer on how the layout is impacting power and performance of the design.
• Physical Verification. This is the final step before the design is sent to manufacturing. All of the physical effects that the manufacturing process adds to the design can now be modeled. Added resistance from wiring, signal crosstalk, and variability in the manufacturing process itself are some of the many items that must be considered here. Will the circuit still work correctly under these stresses? In addition, there are many design rules regarding how the circuit must be physically laid out on the silicon wafer to ensure it will be manufacturable. These design rules are checked at this step as well. Once this process is completed, the design is ready for ¡°signoff,¡± a step where all of the required checks are verified as correct and the design is submitted to manufacturing or used in subsequent semi-custom or ASIC designs.

The ²ÝÁñÉçÇø Custom Design Platform is a unified suite of design and verification tools that accelerates the development of robust custom analog designs. Built on the Custom Compiler? custom design environment, the platform features industry-leading circuit simulation performance, a fast and easy-to-use layout editor, and best-in-class technologies for parasitic extraction, reliability analysis, and physical verification.

Platform tools include:

• Custom Compiler: providing design entry, simulation management and analysis, and custom layout editing features
• FineSim:  a multi-core/multi-machine simulator that is well-suited for the simulation of large, complex analog and RF circuits
• IC Validator: a comprehensive and high-performance signoff physical verification solution that improves productivity for customers at all process nodes
• HSPICE: the gold standard for accurate on-chip simulation and silicon-to-package-to-board-to-backplane signal integrity simulation and analysis
• StarRC: the gold standard for parasitic extraction
• CustomSim: featuring the FastSPICE simulator, which delivers superior verification performance and capacity for all classes of design
• Custom WaveView: a graphical waveform viewer and simulation post-processing tool for analog and mixed-signal ICs
• SiliconSmart: a comprehensive array of library characterization and QA capabilities to generate the models required for digital signoff tools such as PrimeTime
• Reliability Analysis: HSPICE, FineSim, and CustomSim support a comprehensive set of reliability and Monte Carlo analysis features to ensure circuits operate correctly in the face of variability