about
Evolvable Smartphone-Based Platforms for Point-of-Care In-Vitro Diagnostics Applications.Simulation Approach for Timing Analysis of Genetic Logic Circuits.D-VASim: an interactive virtual laboratory environment for the simulation and analysis of genetic circuits.Paper-based sensors for rapid detection of virulence factor produced by Pseudomonas aeruginosaPin-count reduction for continuous flow microfluidic biochipsA systematic and practical method for selecting systems engineering toolsLogic analysis and verification of n-input genetic logic circuitsPaper-Based Digital Microfluidic Chip for Multiple Electrochemical Assay Operated by a Wireless Portable Control SystemScheduling and Fluid Routing for Flow-Based Microfluidic Laboratories-on-a-ChipSynthesis of on-chip control circuits for mVLSI biochipsSystem-Level Sensitivity Analysis of SiNW-bioFET-Based Biosensing Using Lock-In AmplificationTaming Living Logic Using Formal MethodsTest-driven modeling and development of cloud-enabled cyber-physical smart systemsVolume management for fault-tolerant continuous-flow microfluidicsWaste-aware fluid volume assignment for flow-based microfluidic biochipsA pin-count reduction algorithm for flow-based microfluidic biochipsMicrofluidic Very Large Scale Integration (VLSI)Model-Based Evaluation of System Scalability: Bandwidth Analysis for Smartphone-Based Biosensing ApplicationsSmartphone-based biosensing platform evolution: Implementation of electrochemical analysis capabilitiesSynthesis of Application-Specific Fault-Tolerant Digital Microfluidic Biochip ArchitecturesA Smart Mobile Lab-on-Chip-Based Medical Diagnostics System Architecture Designed for EvolvabilityFault-Tolerant Digital Microfluidic BiochipsIntroductionRedundancy optimization for error recovery in digital microfluidic biochipsSystem-level synthesis of multi-ASIP platforms using an uncertainty modelTest-driven modeling of embedded systemsEHRA: Specification and Analysis of Energy-Harvesting Wireless Sensor NetworksEnergy Harvesting - Wireless Sensor Networks for Indoors Applications Using IEEE 802.11ASAM: Automatic architecture synthesis and application mappingApplication-specific fault-tolerant architecture synthesis for digital microfluidic biochipsControl synthesis for the flow-based microfluidic large-scale integration biochipsHierarchical DSE for multi-ASIP platformsModule-Based Synthesis of Digital Microfluidic Biochips with Droplet-Aware Operation ExecutionMulti-ASIP platform synthesis for Event-Triggered applications with cost/performance trade-offsMulti-ASIP platform synthesis for real-time applicationsQuality-driven model-based design of multi-processor embedded systems for highlydemanding applicationsASAM: Automatic Architecture Synthesis and Application MappingArchitectural synthesis of flow-based microfluidic large-scale integration biochipsBiochips: The integrated circuit of biologyMDM: A Mode Diagram Modeling Framework
P50
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P50
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professor ved DTU
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Jan Madsen
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