1.Aimsand scope.Radiation Detection Technology and Methods(RDTM)focuses on all aspects of radiation detection technology and methods,including electronics and system design,computer and control techniques,detection te...1.Aimsand scope.Radiation Detection Technology and Methods(RDTM)focuses on all aspects of radiation detection technology and methods,including electronics and system design,computer and control techniques,detection technology and methods,data processing and imaging.It presents an attractive mix of authoritative and comprehensive reviews,original articles on cutting-edge research and brief communications.The journal offers rapid review and publication of articles.展开更多
1.Aims and scope.Radiation Detection Technology and Methods(RDTM)focuses on all aspects of radiation detection technology and methods,including electronics and system design,computer and control techniques,detection t...1.Aims and scope.Radiation Detection Technology and Methods(RDTM)focuses on all aspects of radiation detection technology and methods,including electronics and system design,computer and control techniques,detection technology and methods,data processing and imaging.It presents an attractive mix of authoritative and comprehensive reviews,original articles on cutting-edge research and brief communications.The journal offers rapid review and publication of articles.展开更多
The ever-increasing comptexity of design processes fosters novet design computation modets to be employed in architecturat research and design in order to facilitate accurate data processing and refined decision makin...The ever-increasing comptexity of design processes fosters novet design computation modets to be employed in architecturat research and design in order to facilitate accurate data processing and refined decision making. These computation modets have enabled designers to work with comptex geometry and numeric design constraints to explore a whole new design field that is impossibte to explore without computation techniques. However, most current design computation modets foUow an automation-oriented paradigm that only dear with strictty defined problem solving and optimization, but fail in estabtishing an intuitive and interactive communication with designers. This lack of interaction reads to an unconscious rejection of non-parameterizabte design factors, which, reduces design computation models to specific design probtem sotving toots instead of operating as active design partners. This paper presents a non-deterministic design computation modeling approach derived from a discussion on quantum design paradigm, which emptoys rear-time user interaction as the co-driver to evotve user+computation driven informed design outputs. model; O.PC Tootset, developed and applied in A case study of such a design computation a QuantumPointCloud workshop, will be illustrated in this paper. Expanded discussions on fabrication optimization and construction techniques from the QPC workshop will be addressed to conclude a comprehensive report.展开更多
文摘1.Aimsand scope.Radiation Detection Technology and Methods(RDTM)focuses on all aspects of radiation detection technology and methods,including electronics and system design,computer and control techniques,detection technology and methods,data processing and imaging.It presents an attractive mix of authoritative and comprehensive reviews,original articles on cutting-edge research and brief communications.The journal offers rapid review and publication of articles.
文摘1.Aims and scope.Radiation Detection Technology and Methods(RDTM)focuses on all aspects of radiation detection technology and methods,including electronics and system design,computer and control techniques,detection technology and methods,data processing and imaging.It presents an attractive mix of authoritative and comprehensive reviews,original articles on cutting-edge research and brief communications.The journal offers rapid review and publication of articles.
文摘The ever-increasing comptexity of design processes fosters novet design computation modets to be employed in architecturat research and design in order to facilitate accurate data processing and refined decision making. These computation modets have enabled designers to work with comptex geometry and numeric design constraints to explore a whole new design field that is impossibte to explore without computation techniques. However, most current design computation modets foUow an automation-oriented paradigm that only dear with strictty defined problem solving and optimization, but fail in estabtishing an intuitive and interactive communication with designers. This lack of interaction reads to an unconscious rejection of non-parameterizabte design factors, which, reduces design computation models to specific design probtem sotving toots instead of operating as active design partners. This paper presents a non-deterministic design computation modeling approach derived from a discussion on quantum design paradigm, which emptoys rear-time user interaction as the co-driver to evotve user+computation driven informed design outputs. model; O.PC Tootset, developed and applied in A case study of such a design computation a QuantumPointCloud workshop, will be illustrated in this paper. Expanded discussions on fabrication optimization and construction techniques from the QPC workshop will be addressed to conclude a comprehensive report.
