DFT is an annual Symposium providing an open forum for presentations in the field of defect and fault tolerance in VLSI and nanotechnology systems inclusive of emerging technologies, RISC-V architectures and AI-based solutions. One of the unique features of this symposium is to combine new academic research with state-of-the-art industrial data, necessary ingredients for significant advances in this field. All aspects of design, manufacturing, test, reliability, availability, and security that are affected by defects during manufacturing and by faults during system operation are of interest. Topics include (but are not limited to) the following:

1. Yield Analysis and Modeling: Advanced yield models, defect/fault analysis, statistical modeling, and critical area analysis.
2. Testing Techniques: Innovative testing methodologies for digital, analog, and mixed signal circuits, including built-in self-test, delay fault testing, online test and 2.5D/3D circuits.
3. Design For Testability: DFT for modern ICs, including FPGAs, SoCs, NoCs, GPUs, ASICs, low-power designs, and RISC-V designs.
4. Error Detection, Correction, and Recovery: Robust error handling strategies, including error-control coding, fault masking, and recovery schemes, using hardware/software techniques and architectural approaches.
5. Dependability Analysis and Validation:Rigorous evaluation of system dependability, employing fault injection, cross-layer reliability analysis, and AI/ML-based methods.
6. Repair, Restructuring and Reconfiguration: Dynamic adaptation techniques for fault tolerance and resilience, including self-healing reconfigurable circuits, and on-line repair.
7. Defect and Fault Tolerance: Design of reliable systems in the presence of defects and faults, design space exploration for dependable systems, in critical applications and addressing transient/soft faults.
8. Aging and Radiation effects: Radiation effects, radiation-induced errors in nano-technologies, modeling radiation environments, development of novel radiation test and simulation techniques and developing radiation hardened designs.
9. Aging and Lifetime Reliability
Understanding aging mechanisms, designing for long-term reliability, and managing thermal and variability challenges.
10. Emerging Technologies: Error management strategies for quantum computing, memristive devices, spintronics, microfluidics, and approximate computing.
11. RISC-V: Use of open ISAs in dependable and security applications.
12. Design for Security: Protecting ICs against fault attacks, hardware trojans, and other security threats, the interplay between security, reliability, and trust.
13. Dependable Applications and Case Studies: Real world applications of dependability techniques in 2.5D/3D ICs, IoT, automotive, aerospace, autonomous systems, and AI systems.
14. Sustainability and Green EEE: Highlight the need for energy-efficient and environmentally friendly EEE designs, including low-power design techniques and green manufacturing processes.