A pioneer and leading multidisciplinary conference, ISQED accepts and promotes papers related to the manufacturing, design and EDA. Authors are invited to submit papers in the various disciplines of high level design, circuit design (digital, analog, mixed-signal, RF), test & verification, design automation tools; processes; flows, device modeling, semiconductor technology, advance packaging, and biomedical & bioelectronic devices. All past Conference proceedings & Papers have been published in IEEE Xplore digital library and indexed by Scopus.

The details of various topics of paper submission are as follows:

 
EDA Tools and Methodologies & Agentic AI (EDA)

    Agentic AI for Electronic Design and Design Automation (AI): Systems and hardware enabling autonomous, goal-driven AI agents, including cognitive computing, neuromorphic architectures, and secure AI accelerators. Covering design, implementation, and applications in intelligent interaction and cognitive environments.
    EDA tools, design flows, and physical design methodologies for digital, analog, and mixed-signal systems
    Tools for analyzing and mitigating variation, aging effects, and soft errors
    Design, verification, and maintenance of hard and soft IP blocks
    Integration, testing, qualification, and manufacturing of IP from diverse vendors
    EDA tools for emerging application domains such as smart power grids and renewable energy systems
    Design automation methodologies for 3D ICs, heterogeneous integration, and advanced packaging
    Modeling and simulation of semiconductor devices and processes (TCAD)
    CAD techniques for bio-inspired and neuromorphic computing systems
    EDA tools and methods for photonic devices, circuit, and system design
    EDA for MEMS and other micro/nano-scale systems
    Other topics related to design automation tools, platforms, and methodologies

Hardware and System Security (HSS)

    Attacks and countermeasures, including side-channel attacks, reverse engineering, hardware Trojans, and physical tampering
    Hardware-based security primitives such as physically unclonable functions (PUFs), true random number generators (TRNGs), and lightweight cryptographic ciphers
    Security, privacy, and trust protocols; secure information flow; and trusted execution environments
    Trust establishment using untrusted tools, third-party IP, AI/ML models, and fabrication/manufacturing services
    Secure hardware architectures and memory systems
    Post-quantum cryptographic and security primitives for hardware platforms
    Security challenges and design opportunities in emerging nanoscale devices and technologies
    Internet of Things (IoT) and cyber-physical system (CPS) security at the hardware and system levels
    Other topics related to hardware, embedded, and system-level security

Design Test and Verification (DTV)

    Formal, assertion-based, simulation-based, and hybrid verification techniques for hardware and software systems
    Design-for-Testability (DFT), Automatic Test Equipment (ATE), and Built-In Self-Test (BIST) for digital, analog/mixed-signal, SoC, and memory components
    Test synthesis and synthesis-for-testability for improved coverage and quality
    Fault diagnosis, IDDQ testing, novel test methods, fault modeling, ATPG, and DPPM prediction
    SoC and IP testing strategies, including hierarchical and system-level test approaches
    Design methodologies linking testability to manufacturing and yield improvement
    Hardware/software co-verification and co-validation strategies
    Advanced verification methodologies and testbenches, including UVM, HDLs, and HVLs
    Formal and semi-formal validation techniques supporting functional safety and security
    Self-checking testbenches and novel methods for analog/mixed-signal verification
    Any other emerging topics related to design test and verification

Emerging Device and Process Technologies and Applications (EDPT)

    Design, simulation, and modeling of emerging solid-state devices and materials
    Emerging non-volatile memory and logic technologies, such as STT-RAM, PC-RAM, RRAM, and memristors
    Applications of emerging devices in advanced computing domains including cognitive, neuromorphic, and quantum computing
    Qubit technologies and quantum circuits for quantum information processing
    Specialty device technologies, including MEMS, NEMS, and other nanoelectronic devices
    Design-Technology Co-Optimization (DTCO) methodologies across ASIC, FPGA, RF, memory, and custom/semi-custom designs
    Advanced-node manufacturing techniques, including EUV lithography, DSA, and multiple patterning
    Advanced interconnect solutions such as air-gap structures and silicon photonics
    Modeling and optimization of emerging technology impact on power, performance, area, cost, and reliability
    Design methods and tools for improving yield, manufacturability, and process robustness
    Other topics relevant to emerging device, process, and integration technologies

Circuit Design, 3D Integration and Advanced Packaging (ICAP)

    Low-power, high-performance, and reliable design of digital, analog, RF, memory, interconnect, programmable logic, and FPGA circuits
    Techniques for leakage reduction, dynamic/static power optimization, and power management
    Analog and mixed-signal circuit design, including all-digital PLLs/DLLs, ADCs, and DACs
    Adaptive and resilient circuit techniques for variability and fault tolerance
    On-chip sensors and monitors for process, voltage, temperature, and aging variations
    Hardware design for IoT systems, including digital logic, memory, wireless interfaces, energy harvesting, signal processing, and power management
    Advanced packaging technologies including 3D ICs, 2.5D interposers, and multi-chip modules and their impact on design methodologies
    Design techniques and flows for vertically integrated circuits and chips
    Modeling and mitigation of inter-die and inter-layer interactions in 3D ICs
    Design of die-to-die and chip-to-chip interfaces for 2.5D/3D integration
    Design-for-testability, yield enhancement, and system-level design considerations in 3D/2.5D ICs
    Die-package co-design and integration challenges
    Other topics related to circuit design, 3D integration, and advanced packaging technologies

System-level Design and Methodologies (SDM)

    Design methods for complex systems including multi-core processors, embedded systems, SoCs, GPUs, accelerators, and heterogeneous architectures
    System-level trade-off analysis and multi-objective optimization (e.g., yield, power, performance, area, and cost)
    Power and thermal management techniques at the system level
    Modeling and simulation frameworks to assess the impact of process, voltage, temperature, and aging variations on system performance and reliability
    System-level implications and integration of emerging technologies
    Cyber-Physical Systems (CPS): design methodologies, tools, and reliability analysis
    Hardware/software co-design, co-simulation, co-optimization, and design-space exploration
    Prototyping and emulation of hardware/software systems using FPGAs
    Microarchitectural transformations and optimization techniques
    System communication and interconnect architecture, including Network-on-Chip (NoC) methodologies
    Application-driven design of heterogeneous computing platforms
    Any other topics related to system-level design, modeling, and co-optimization

Cognitive Computing Hardware (CCH)

    Neuromorphic computing, non-Von Neumann architectures, and brain-inspired hardware paradigms
    Hardware and architectures for neural networks, including deep learning and spiking neural networks
    Neural network acceleration using GPGPUs, FPGAs, dedicated ASICs, and custom silicon
    Cognitive-inspired computing systems and fundamentals for intelligent information processing
    AI-assisted cognitive computing methods and hardware/software co-design approaches
    Hardware support for secure and reliable machine learning and cognitive applications
    Cognitive computing in large-scale systems: big data processing, sensing, and interaction
    Brain analysis and neuroscience-driven models for hardware design
    Internet of Cognitive Things, cognitive environments, and data-driven sensing systems
    Cognitive robots, intelligent agents, and edge intelligence platforms
    Security and trust challenges in cognitive-inspired computing systems
    Testbeds, prototype implementations, and emerging applications of cognitive hardware
    Other topics related to cognitive and intelligent computing hardware