[Seminar] Basics and Applications of Analog Technology Supporting FPGA / SoC
Essential for FPGA/SoC designers! The essence of analog technology that influences system stability.
To everyone involved in the design of digital systems utilizing FPGAs and SoCs. "Even though it should be according to specifications, for some reason the system is unstable..." "Aren't you troubled by issues such as noise, heat generation, and signal quality?" In the rapidly advancing fields of high-speed and high-density digital design, knowledge of analog technology is essential for ensuring system reliability. However, digital designers often have few opportunities to systematically learn about analog technology. In this seminar, leading instructors will clearly explain the fundamentals of analog technology that are crucial for ensuring the reliable operation of FPGA/SoC digital systems. We will select themes directly related to challenges faced in the field, such as wiring delays, power supply, thermal design, and noise countermeasures. This is a great opportunity to learn the key points of analog technology that you may feel hesitant to ask about from a digital design perspective. Please take advantage of this seminar to elevate the quality and reliability of your products to the next level. 【Recommended for】 Designers of digital circuits primarily based on FPGAs and SoCs Those who feel challenges in improving system stability and reliability Those who want to gain a broader perspective of the entire system and enhance their troubleshooting skills.
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1. Overview 2. Wiring and Delay - Analog Techniques Applicable to System Design 2.1. Wiring 2.2. Signal Transmission Between Boards 2.2.1. Connector Connection - Pin Arrangement Innovations from the Perspective of Standard I/F (such as Compact PCI) 2.2.2. Harness Connection - Signal Arrangement Innovations from the Perspective of Standard I/F (such as SCSI) 3. Wiring Delay and Timing - Digital Signals are Analog Techniques 3.1. Wiring Delay and Timing 3.2. Signal Transmission and Component Placement - Analog Techniques for Wiring... Circuit Design and PCB Design, Component Placement, and Wiring Instructions 4. Power (Drive/Output) Circuits 4.1. Basics and Practices of Emitter (Source) Grounding (Switching) - Switching Behavior and Practices of Transistors and FETs 4.2. Basics and Practices of Emitter (Source) Followers - Behavior and Practices of Transistors and FETs 5. Thermal Design and Reliability 5.1. Designing for Reliability - Heat Generation and Failure, Derating 5.2. Heat Dissipation Design for Semiconductors - Thermal Resistance and Heat Dissipation 6. Radiation and Noise 6.1. Electrostatic Discharge 6.2. Power Supply Interference 6.3. Unwanted Radiation 7. Analog Techniques in Digital Systems - Analog Techniques Used in Actual System Design
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1. Improvement of Design Quality and Product Reliability Many issues with digital circuits, such as "not working for some reason" or "becoming unstable," are caused by analog factors like noise, heat, and signal quality. By learning the basics and countermeasures in this seminar, you will acquire the ability to design reliable systems that operate stably with minimal rework. This directly contributes to improving product quality. 2. Enhancement of Development Efficiency and Troubleshooting Skills You can significantly reduce the time spent on identifying the causes of problems and debugging. By understanding the key points of analog technology, you can quickly isolate issues and implement appropriate countermeasures. This helps prevent unexpected troubles in the later stages of development and contributes to the overall efficiency of the development schedule. 3. Acquisition of Systematic Knowledge that Bridges the "Wall" between Digital and Analog This seminar dispels the mindset often held by FPGA/SoC designers that "I understand digital, but I'm not good at analog." You will systematically learn about themes such as wiring, power supply, heat, and noise from the perspective of digital designers, allowing previously fragmented knowledge to connect and fostering the ability to design with a holistic view of the entire system. 4. Acquisition of Practical Know-How that Can Be Used Immediately in the Field
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A Challenge to Transform "Impossible" into "Possible" in Design Quality One day, we received a development project for a new wearable device that pursued unprecedented thinness and lightness. The client's request was, "It must be completely waterproof while not compromising on design at all." The project initially ran aground due to this conflicting challenge. The thickness of the casing was just a few millimeters. With conventional waterproofing technology, it was not only difficult to protect the internal precision instruments but also to maintain design integrity. While many engineers threw in the towel, declaring it "impossible," the challenge at Kamigami Corporation began. Our team first thoroughly utilized 3D data as part of our DX promotion, repeatedly conducting simulations in a virtual space. This was a crucial process to eliminate rework and improve development productivity. Drawing on the experience and insights that our representative, Suzuki, had cultivated over many years in developing some of the world's thinnest waterproof designs for smartphones, we meticulously analyzed every possible water intrusion route, leaving no 0.1 millimeter gap unchecked. We pursued the highest design quality and devised a new waterproof structure that overturned conventional wisdom.
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