Difference between revisions of "ASP-DAC 2020"
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Original papers in, but not limited to, the following areas are invited. | Original papers in, but not limited to, the following areas are invited. | ||
− | 1. System-Level Modeling and Design Methodology: | + | * 1. System-Level Modeling and Design Methodology: |
− | 1.1. HW/SW co-design, co-simulation and co-verification | + | * 1.1. HW/SW co-design, co-simulation and co-verification |
− | 1.2. System-level design exploration, synthesis and optimization | + | * 1.2. System-level design exploration, synthesis and optimization |
− | 1.3. System-level formal verification | + | * 1.3. System-level formal verification |
− | 1.4. System-level modeling, simulation and validation tools/methodology | + | * 1.4. System-level modeling, simulation and validation tools/methodology |
− | + | * | |
− | 2. Embedded Systems and Cyberphysical Systems: | + | * 2. Embedded Systems and Cyberphysical Systems: |
− | 2.1. Many- and multi-core SoC architecture | + | * 2.1. Many- and multi-core SoC architecture |
− | 2.2. IP/platform-based SoC design | + | * 2.2. IP/platform-based SoC design |
− | 2.3. Domain-specific architecture | + | * 2.3. Domain-specific architecture |
− | 2.4. Dependable architecture | + | * 2.4. Dependable architecture |
− | 2.5. Cyber physical system | + | * 2.5. Cyber physical system |
− | 2.6. Internet of things | + | * 2.6. Internet of things |
− | + | * | |
− | 3. Embedded Systems Software: | + | * 3. Embedded Systems Software: |
− | 3.1. Kernel, middleware and virtual machine | + | * 3.1. Kernel, middleware and virtual machine |
− | 3.2. Compiler and toolchain | + | * 3.2. Compiler and toolchain |
− | 3.3. Real-time system | + | * 3.3. Real-time system |
− | 3.4. Resource allocation for heterogeneous computing platform | + | * 3.4. Resource allocation for heterogeneous computing platform |
− | 3.5. Storage software and application | + | * 3.5. Storage software and application |
− | 3.6. Human-computer interface | + | * 3.6. Human-computer interface |
− | + | * | |
− | 4. Memory Architecture and Near/In Memory Computing: | + | * 4. Memory Architecture and Near/In Memory Computing: |
− | 4.1. Storage system and memory architecture | + | * 4.1. Storage system and memory architecture |
− | 4.2. On-chip memory architectures and management: Scratchpads, compiler, controlled memories, etc. | + | * 4.2. On-chip memory architectures and management: Scratchpads, compiler, controlled memories, etc. |
− | 4.3. Memory and storage hierarchies with emerging memory technologies | + | * 4.3. Memory and storage hierarchies with emerging memory technologies |
− | 4.4. Near-memory and in-memory computing | + | * 4.4. Near-memory and in-memory computing |
− | 4.5. Memory architecture and management for emerging memory technologies | + | * 4.5. Memory architecture and management for emerging memory technologies |
− | + | * | |
− | 5. Neural Network and Neuromorphic Computing: | + | * 5. Neural Network and Neuromorphic Computing: |
− | 5.1. Hardware and devices for neuromorphic and neural network computing | + | * 5.1. Hardware and devices for neuromorphic and neural network computing |
− | 5.2. Design method for learning on a chip | + | * 5.2. Design method for learning on a chip |
− | 5.3. Systems for neural computing (including deep neural networks) | + | * 5.3. Systems for neural computing (including deep neural networks) |
− | 5.4. Neural network acceleration techniques including GPGPU, FPGA and dedicated ASICs | + | * 5.4. Neural network acceleration techniques including GPGPU, FPGA and dedicated ASICs |
− | 5.5. CAD for bio-inspired and neuromorphic systems | + | * 5.5. CAD for bio-inspired and neuromorphic systems |
− | + | * | |
− | 6. Analog, RF, Mixed Signal, and Photonics: | + | * 6. Analog, RF, Mixed Signal, and Photonics: |
− | 6.1. Analog/mixed-signal/RF synthesis | + | * 6.1. Analog/mixed-signal/RF synthesis |
− | 6.2. Analog layout, verification, and simulation techniques | + | * 6.2. Analog layout, verification, and simulation techniques |
− | 6.3. High-frequency electromagnetic simulation of circuit | + | * 6.3. High-frequency electromagnetic simulation of circuit |
− | 6.4. Mixed-signal design consideration | + | * 6.4. Mixed-signal design consideration |
− | 6.5. Communication architectures using nanophotonics, RF, 3D, etc. | + | * 6.5. Communication architectures using nanophotonics, RF, 3D, etc. |
− | 6.6. Networks-on-chip and NoC-based system design | + | * 6.6. Networks-on-chip and NoC-based system design |
− | + | * | |
− | 7. Lower Power Design and Approximate Computing: | + | * 7. Lower Power Design and Approximate Computing: |
− | 7.1. Power modeling, analysis and simulation | + | * 7.1. Power modeling, analysis and simulation |
− | 7.2. Low-power design and methodology | + | * 7.2. Low-power design and methodology |
− | 7.3. Thermal aware design | + | * 7.3. Thermal aware design |
− | 7.4. Energy harvesting and battery management | + | * 7.4. Energy harvesting and battery management |
− | 7.5. Hardware techniques for approximate/stochastic computing | + | * 7.5. Hardware techniques for approximate/stochastic computing |
− | + | * | |
− | 8. Logic/High-Level Synthesis and Optimization: | + | * 8. Logic/High-Level Synthesis and Optimization: |
− | 8.1. High-level synthesis tool and methodology | + | * 8.1. High-level synthesis tool and methodology |
− | 8.2. Combinational, sequential and asynchronous logic synthesis | + | * 8.2. Combinational, sequential and asynchronous logic synthesis |
− | 8.3. Logic synthesis and physical design technique for FPGA | + | * 8.3. Logic synthesis and physical design technique for FPGA |
− | 8.4. Technology mapping | + | * 8.4. Technology mapping |
− | + | * | |
− | 9. Physical Design: | + | * 9. Physical Design: |
− | 9.1. Floorplanning, partitioning and placement | + | * 9.1. Floorplanning, partitioning and placement |
− | 9.2. Interconnect planning and synthesis | + | * 9.2. Interconnect planning and synthesis |
− | 9.3. Placement and routing optimization | + | * 9.3. Placement and routing optimization |
− | 9.4. Clock network synthesis | + | * 9.4. Clock network synthesis |
− | 9.5. Post layout and post-silicon optimization | + | * 9.5. Post layout and post-silicon optimization |
− | 9.6. Package/PCB/3D-IC routing | + | * 9.6. Package/PCB/3D-IC routing |
− | + | * | |
− | 10. Design for Manufacturability and Reliability: | + | * 10. Design for Manufacturability and Reliability: |
− | 10.1. Reticle enhancement, lithography-related design and optimization | + | * 10.1. Reticle enhancement, lithography-related design and optimization |
− | 10.2. Resilience under manufacturing variation | + | * 10.2. Resilience under manufacturing variation |
− | 10.3. Design for manufacturability, yield, and defect tolerance | + | * 10.3. Design for manufacturability, yield, and defect tolerance |
− | 10.4. Reliability, aging and soft error analysis | + | * 10.4. Reliability, aging and soft error analysis |
− | 10.5. Design for reliability, aging, and robustness | + | * 10.5. Design for reliability, aging, and robustness |
− | 10.6. Machine learning for smart manufacturing and process control | + | * 10.6. Machine learning for smart manufacturing and process control |
− | + | * | |
− | 11. Timing and Signal/Power Integrity: | + | * 11. Timing and Signal/Power Integrity: |
− | 11.1. Deterministic/statistical timing and performance analysis and optimization | + | * 11.1. Deterministic/statistical timing and performance analysis and optimization |
− | 11.2. Power/ground and package modeling, analysis and optimization | + | * 11.2. Power/ground and package modeling, analysis and optimization |
− | 11.3. Signal/power integrity, EM modeling and analysis | + | * 11.3. Signal/power integrity, EM modeling and analysis |
− | 11.4. Extraction, TSV and package modeling | + | * 11.4. Extraction, TSV and package modeling |
− | 11.5. 2D/3D on-chip power delivery network analysis and optimization | + | * 11.5. 2D/3D on-chip power delivery network analysis and optimization |
− | + | * | |
− | 12. Testing, Validation, Simulation, and Verification: | + | * 12. Testing, Validation, Simulation, and Verification: |
− | 12.1. ATPG, BIST and DFT | + | * 12.1. ATPG, BIST and DFT |
− | 12.2. System test and 3D IC test | + | * 12.2. System test and 3D IC test |
− | 12.3. Online test and fault tolerance | + | * 12.3. Online test and fault tolerance |
− | 12.4. Memory test and repair | + | * 12.4. Memory test and repair |
− | 12.5. RTL and gate-leveling modeling, simulation, and verification | + | * 12.5. RTL and gate-leveling modeling, simulation, and verification |
− | 12.6. Circuit-level formal verification | + | * 12.6. Circuit-level formal verification |
− | 12.7. Device/circuit-level simulation tool and methodology | + | * 12.7. Device/circuit-level simulation tool and methodology |
− | + | * | |
− | 13. Hardware and Embedded Security: | + | * 13. Hardware and Embedded Security: |
− | 13.1. Hardware-based security | + | * 13.1. Hardware-based security |
− | 13.2. Detection and prevention of hardware Trojans | + | * 13.2. Detection and prevention of hardware Trojans |
− | 13.3. Side-channel attacks, fault attacks and countermeasures | + | * 13.3. Side-channel attacks, fault attacks and countermeasures |
− | 13.4. Design and CAD for security | + | * 13.4. Design and CAD for security |
− | 13.5. Cyberphysical system security | + | * 13.5. Cyberphysical system security |
− | 13.6. Nanoelectronic security | + | * 13.6. Nanoelectronic security |
− | 13.7. Supply chain security and anti-counterfeiting | + | * 13.7. Supply chain security and anti-counterfeiting |
− | + | * | |
− | 14. Emerging Technologies and Applications: | + | * 14. Emerging Technologies and Applications: |
− | 14.1. Biomedical, biochip, and biodata processing | + | * 14.1. Biomedical, biochip, and biodata processing |
− | 14.2. Big/thick data, datacenter | + | * 14.2. Big/thick data, datacenter |
− | 14.3. Advanced multimedia application | + | * 14.3. Advanced multimedia application |
− | 14.4. Energy-storage/smart-grid/smart-building design and optimization | + | * 14.4. Energy-storage/smart-grid/smart-building design and optimization |
− | 14.5. Automotive system design and optimization | + | * 14.5. Automotive system design and optimization |
− | 14.6. New transistor/device and process technology: spintronic, phase-change, single-electron etc. | + | * 14.6. New transistor/device and process technology: spintronic, phase-change, single-electron etc. |
− | 14.7. Nanotechnology, MEMS, quantum computing etc. | + | * 14.7. Nanotechnology, MEMS, quantum computing etc. |
Please note that each paper shall be accompanied by at least one different conference registration at the speaker’s registration rate (e.g., two speaker registrations are needed for presenting two accepted papers). But any registered co-author can present the work at the conference. ACM and IEEE reserve the right to exclude a paper from distribution after the conference (e.g., removal from ACM Digital Library and IEEE Xplore) if the paper is not presented at the conference by the author of the paper. ASP-DAC does not allow double and/or parallel submissions of similar work to any other conferences, symposia, and journals. | Please note that each paper shall be accompanied by at least one different conference registration at the speaker’s registration rate (e.g., two speaker registrations are needed for presenting two accepted papers). But any registered co-author can present the work at the conference. ACM and IEEE reserve the right to exclude a paper from distribution after the conference (e.g., removal from ACM Digital Library and IEEE Xplore) if the paper is not presented at the conference by the author of the paper. ASP-DAC does not allow double and/or parallel submissions of similar work to any other conferences, symposia, and journals. |
Revision as of 13:29, 13 May 2020
ASP-DAC 2020 | |
---|---|
25th Asia and South Pacific Design Automation Conference
| |
Event in series | ASP-DAC |
Dates | 2020/01/13 (iCal) - 2020/01/16 |
Homepage: | https://aspdac2020.github.io/aspdac20/ |
Location | |
Location: | Beijing, China |
Loading map... | |
Important dates | |
Submissions: | 2019/07/12 |
Committees | |
General chairs: | K.-T. Tim Cheng, Huazhong Yang |
PC chairs: | Tsung-Yi Ho |
Table of Contents | |
Contents | |
Call for Papers ASP-DAC 2020
Areas of Interest: Original papers in, but not limited to, the following areas are invited.
- 1. System-Level Modeling and Design Methodology:
- 1.1. HW/SW co-design, co-simulation and co-verification
- 1.2. System-level design exploration, synthesis and optimization
- 1.3. System-level formal verification
- 1.4. System-level modeling, simulation and validation tools/methodology
- 2. Embedded Systems and Cyberphysical Systems:
- 2.1. Many- and multi-core SoC architecture
- 2.2. IP/platform-based SoC design
- 2.3. Domain-specific architecture
- 2.4. Dependable architecture
- 2.5. Cyber physical system
- 2.6. Internet of things
- 3. Embedded Systems Software:
- 3.1. Kernel, middleware and virtual machine
- 3.2. Compiler and toolchain
- 3.3. Real-time system
- 3.4. Resource allocation for heterogeneous computing platform
- 3.5. Storage software and application
- 3.6. Human-computer interface
- 4. Memory Architecture and Near/In Memory Computing:
- 4.1. Storage system and memory architecture
- 4.2. On-chip memory architectures and management: Scratchpads, compiler, controlled memories, etc.
- 4.3. Memory and storage hierarchies with emerging memory technologies
- 4.4. Near-memory and in-memory computing
- 4.5. Memory architecture and management for emerging memory technologies
- 5. Neural Network and Neuromorphic Computing:
- 5.1. Hardware and devices for neuromorphic and neural network computing
- 5.2. Design method for learning on a chip
- 5.3. Systems for neural computing (including deep neural networks)
- 5.4. Neural network acceleration techniques including GPGPU, FPGA and dedicated ASICs
- 5.5. CAD for bio-inspired and neuromorphic systems
- 6. Analog, RF, Mixed Signal, and Photonics:
- 6.1. Analog/mixed-signal/RF synthesis
- 6.2. Analog layout, verification, and simulation techniques
- 6.3. High-frequency electromagnetic simulation of circuit
- 6.4. Mixed-signal design consideration
- 6.5. Communication architectures using nanophotonics, RF, 3D, etc.
- 6.6. Networks-on-chip and NoC-based system design
- 7. Lower Power Design and Approximate Computing:
- 7.1. Power modeling, analysis and simulation
- 7.2. Low-power design and methodology
- 7.3. Thermal aware design
- 7.4. Energy harvesting and battery management
- 7.5. Hardware techniques for approximate/stochastic computing
- 8. Logic/High-Level Synthesis and Optimization:
- 8.1. High-level synthesis tool and methodology
- 8.2. Combinational, sequential and asynchronous logic synthesis
- 8.3. Logic synthesis and physical design technique for FPGA
- 8.4. Technology mapping
- 9. Physical Design:
- 9.1. Floorplanning, partitioning and placement
- 9.2. Interconnect planning and synthesis
- 9.3. Placement and routing optimization
- 9.4. Clock network synthesis
- 9.5. Post layout and post-silicon optimization
- 9.6. Package/PCB/3D-IC routing
- 10. Design for Manufacturability and Reliability:
- 10.1. Reticle enhancement, lithography-related design and optimization
- 10.2. Resilience under manufacturing variation
- 10.3. Design for manufacturability, yield, and defect tolerance
- 10.4. Reliability, aging and soft error analysis
- 10.5. Design for reliability, aging, and robustness
- 10.6. Machine learning for smart manufacturing and process control
- 11. Timing and Signal/Power Integrity:
- 11.1. Deterministic/statistical timing and performance analysis and optimization
- 11.2. Power/ground and package modeling, analysis and optimization
- 11.3. Signal/power integrity, EM modeling and analysis
- 11.4. Extraction, TSV and package modeling
- 11.5. 2D/3D on-chip power delivery network analysis and optimization
- 12. Testing, Validation, Simulation, and Verification:
- 12.1. ATPG, BIST and DFT
- 12.2. System test and 3D IC test
- 12.3. Online test and fault tolerance
- 12.4. Memory test and repair
- 12.5. RTL and gate-leveling modeling, simulation, and verification
- 12.6. Circuit-level formal verification
- 12.7. Device/circuit-level simulation tool and methodology
- 13. Hardware and Embedded Security:
- 13.1. Hardware-based security
- 13.2. Detection and prevention of hardware Trojans
- 13.3. Side-channel attacks, fault attacks and countermeasures
- 13.4. Design and CAD for security
- 13.5. Cyberphysical system security
- 13.6. Nanoelectronic security
- 13.7. Supply chain security and anti-counterfeiting
- 14. Emerging Technologies and Applications:
- 14.1. Biomedical, biochip, and biodata processing
- 14.2. Big/thick data, datacenter
- 14.3. Advanced multimedia application
- 14.4. Energy-storage/smart-grid/smart-building design and optimization
- 14.5. Automotive system design and optimization
- 14.6. New transistor/device and process technology: spintronic, phase-change, single-electron etc.
- 14.7. Nanotechnology, MEMS, quantum computing etc.
Please note that each paper shall be accompanied by at least one different conference registration at the speaker’s registration rate (e.g., two speaker registrations are needed for presenting two accepted papers). But any registered co-author can present the work at the conference. ACM and IEEE reserve the right to exclude a paper from distribution after the conference (e.g., removal from ACM Digital Library and IEEE Xplore) if the paper is not presented at the conference by the author of the paper. ASP-DAC does not allow double and/or parallel submissions of similar work to any other conferences, symposia, and journals.
Submission of Papers:
Deadline for abstract: 5 PM AOE (Anywhere on earth) July 5 (Fri), 2019
Deadline for full paper: 5 PM AOE (Anywhere on earth) July 5 (Fri), 2019 July 12 (Fri), 2019 (extended)
Notification of acceptance: Sep. 9 (Mon), 2019
Deadline for final version: 5 PM AOE (Anywhere on earth) Nov. 4 (Mon), 2019
For detailed instructions for submission and specification of the paper format, please refer to Author's Guide.
Acronym | ASP-DAC 2020 + |
End date | January 16, 2020 + |
Event in series | ASP-DAC + |
Event type | Conference + |
Has coordinates | 40° 11' 26", 116° 24' 44"Latitude: 40.190633333333 Longitude: 116.41214444444 + |
Has general chair | K.-T. Tim Cheng + and Huazhong Yang + |
Has location city | Beijing + |
Has location country | Category:China + |
Has program chair | Tsung-Yi Ho + |
Homepage | https://aspdac2020.github.io/aspdac20/ + |
IsA | Event + |
Start date | January 13, 2020 + |
Submission deadline | July 12, 2019 + |
Title | 25th Asia and South Pacific Design Automation Conference + |