TOOLS

A legally compliant volume is automatically generated for スポーツベット カジノ site shape, and an error judgment is performed to see if スポーツベット カジノ planned building is within スポーツベット カジノ height limit. You can also use this tool to search for スポーツベット カジノ legal maximum volume.

Developed in cooperation with: Algorithm Design Lab, Seikatsu Sangyo Laboratory

スポーツベット カジノ sky factor is automatically calculated for スポーツベット カジノ site and building shape, and スポーツベット カジノ sky map and calculation results are displayed on スポーツベット カジノ Rhinoceros screen. Results are updated in real time as スポーツベット カジノ building shape changes.

Developed in cooperation with: Algorithm Design Lab, Seikatsu Sangyo Laboratory

Create a time-of-day shade map and an isochronous shade map for スポーツベット カジノ planned building. It is also equipped with a check function that colors スポーツベット カジノ building parts that are out of regulation. It enables quick volume studies with simple operation and visualization of regulations.

Developed in cooperation with: Algorithm Design Lab, Seikatsu Sangyo Laboratory

スポーツベット カジノ area is calculated for each room use from スポーツベット カジノ created building model and displayed as a graph on スポーツベット カジノ screen. This area information graph is updated in real time as スポーツベット カジノ building shape changes. By exporting スポーツベット カジノ information as an area table, it can be used for business feasibility evaluation, etc.

This tool creates 3D models of rebars, steel frames, etc., and displays errors for any interfering parts. It becomes possible to verify スポーツベット カジノ detailing of complex joints in 3D.

Evaluate スポーツベット カジノ line of sight from スポーツベット カジノ assumed viewpoint to スポーツベット カジノ target in スポーツベット カジノ planned building shape. This verification enables a variety of studies, such as reviewing スポーツベット カジノ terraced floors of stadiums, theaters, and halls, and examining スポーツベット カジノ designs of louvers that block スポーツベット カジノ line of sight.

Annual outdoor temperatures such as AMeDAS weather data is visualized on a chart. By coloring スポーツベット カジノ outside temperature range of 18-26 °C, it is possible to analyze スポーツベット カジノ seasons and time periods suitable for natural ventilation.

Tools used: ClimateStudio

Calculate スポーツベット カジノ sunlight hours while considering スポーツベット カジノ shadows cast by sunshade devices and obstacles. It is possible to consider outdoor stadium lawns and tree growth in landscapes.

Tools used: ClimateStudio

Calculate スポーツベット カジノ amount of solar radiation that hits スポーツベット カジノ exterior walls and roofs, allowing for studies of window layouts and sunshade planning that considers solar radiation.

Tools used: ClimateStudio

Analyze スポーツベット カジノ wind flow around a building, allowing for building placement with consideration for wind passage, and window layouts for natural ventilation.

Tools used: STREAM

Analyze スポーツベット カジノ ventilation volume, room temperature, and indoor air velocity when natural ventilation is implemented. It is possible to study natural ventilation that is closer to スポーツベット カジノ actual situation, reflecting スポーツベット カジノ effects of outdoor airflow.

Tools used: Archsim, STREAM

Simulate スポーツベット カジノ flow of rainwater that falls on スポーツベット カジノ ground. By visualizing スポーツベット カジノ rainwater trajectory due to スポーツベット カジノ ground surface slope, it is possible to plan assuming for places where rainwater tends to collect and for hazardous areas that flow into スポーツベット カジノ planned site.

Developed in cooperation with: Algorithm Design Lab

スポーツベット カジノ thermal load of スポーツベット カジノ perimeter is calculated while considering heat insulation and solar shielding effect. Thermal weak points are visualized by coloring スポーツベット カジノ building surface, making it possible to consider energy-saving buildings with low thermal loads.

スポーツベット カジノ thermal comfort PMV is calculated by analyzing スポーツベット カジノ radiant environment considering スポーツベット カジノ heat insulation and スポーツベット カジノ solar shielding effect. It can also be used for airflow windows and push-pull windows, allowing for façade studies to realize a comfortable indoor environment.

Tools used: ClimateStudio

スポーツベット カジノ annual illuminance distribution, brightness distribution, and energy-saving effect of natural lighting and electric lighting are calculated. It is possible to study window layouts and sunshade plans to realize an energy-saving and bright indoor environment.

Tools used: ClimateStudio

Calculate スポーツベット カジノ annual discomfort glare rate at multiple points in スポーツベット カジノ room. It is possible to verify スポーツベット カジノ glare when natural lighting is used, and to consider window layouts and sunshade plans to realize a comfortable light environment. (DGP is used for スポーツベット カジノ glare index.)

Tools used: ClimateStudio

Analyze スポーツベット カジノ distribution of indoor temperature and indoor air velocity in large spaces such as arenas and gymnasiums. By devising an air flow model, analysis time can be reduced, and multiple proposals can be analyzed in a short time, allowing for studies of optimal placement of supply and return registers.

Tools used: STREAM

スポーツベット カジノ optimal solution can be derived quantitatively using different approaches: (1) brute force method - narrow down スポーツベット カジノ solution from a vast number of parametrically generated proposals by setting multiple target values or (2) multi-purpose optimization using a genetic algorithm.

Tools used: (1) Shimz Explorer (Developed in cooperation with: Thornton Tomasetti / CORE Studio, Algorithm Design Lab); (2) Octopus, modeFRONTIER

Once you set スポーツベット カジノ start and finish points, スポーツベット カジノ shortest path of circulation is calculated. By overlapping スポーツベット カジノ paths from each room to スポーツベット カジノ frequently used rooms, it is possible to visualize daily flow and locations of high interactivity in スポーツベット カジノ building.

Visualize スポーツベット カジノ relationship between spaces with different uses, such as department offices and specific function rooms. スポーツベット カジノ size of スポーツベット カジノ space is exhibited by スポーツベット カジノ size of スポーツベット カジノ circle, and スポーツベット カジノ depth of スポーツベット カジノ relationship, such as スポーツベット カジノ frequency of meetings, is displayed by スポーツベット カジノ thickness and color of スポーツベット カジノ line. By switching スポーツベット カジノ display, it is possible to perform スポーツベット カジノ 2D zoning by freely moving スポーツベット カジノ circles while studying スポーツベット カジノ space in スポーツベット カジノ 3D model at スポーツベット カジノ same time.

A tool that supports スポーツベット カジノ "ground plane" and "average ground" calculations, based on which スポーツベット カジノ setback restrictions and shadow restrictions are determined for スポーツベット カジノ volume studies at スポーツベット カジノ initial stage of design. A ground plane development map and a ground plane calculation table are automatically generated from スポーツベット カジノ three-dimensional model reflecting スポーツベット カジノ site gradient and スポーツベット カジノ building perimeter shape. Information is updated in real time when スポーツベット カジノ shape is changed, enabling quick examination.

Calculate スポーツベット カジノ consumption of electricity, gas, water supply, etc. of スポーツベット カジノ HVAC system that uses スポーツベット カジノ most energy in スポーツベット カジノ building, allowing for studies of HVAC configurations that are energy-saving and have low running costs.

スポーツベット カジノ "sense of brightness" felt by スポーツベット カジノ human eye is evaluated using スポーツベット カジノ brightness scale value (NB value). Unlike conventional evaluations based on illuminance, this allows for planning of daylighting and electric lighting based on スポーツベット カジノ brightness perceived by humans.

Tools used: REALAPS, ClimateStudio

A tool to generate terrain mesh in Rhinoceros from survey maps. Based on スポーツベット カジノ generated terrain, it becomes possible to analyze and visualize スポーツベット カジノ 3D terrain by various methods such as soil volume, contour line display, and gradient determination.

スポーツベット カジノ visibility of スポーツベット カジノ ball at any position in スポーツベット カジノ indoor stadium is evaluated based on スポーツベット カジノ contrast with スポーツベット カジノ background brightness. Natural lighting and electric lighting plans can be created while considering スポーツベット カジノ visibility of high side lights.

Tools used: REALAPS

スポーツベット カジノ reflected light from スポーツベット カジノ building’s exterior wall surface is estimated using スポーツベット カジノ direction of solar radiation utilized in environmental simulations. スポーツベット カジノ geometry and rays of reflected light from solar radiation can be projected to スポーツベット カジノ surroundings.

Tools used: Ladybug、Wombat、Sasquatch、TT Toolbox (Colibri)

This tool generates a ground structure (a structure in which all nearby nodes are connected by members) and derives スポーツベット カジノ most efficient shape (topology-optimized form) to スポーツベット カジノ given external forces and support conditions.

Tools used: Karamba 3D

A model with loads, boundary conditions, and other factors, is created to conduct structural analysis. Structural safety is verified by checking deformation, member stresses, etc.

Tools used:Karamba 3D, EEL

This system generates a structural framework based on スポーツベット カジノ building volume and allocates member sections using AI. This makes it possible to streamline structural review in スポーツベット カジノ early stages of design.

Tools used：SYMPREST

Development collaboration：Headwaters Co., Ltd. and Headwaters Consulting Co., Ltd.

スポーツベット カジノ target space is modeled as a network by setting entrances, exits, and branch points as nodes and using スポーツベット カジノ connecting routes and corridors as links. Parameters such as スポーツベット カジノ movement purpose, movement route, walking speed, スポーツベット カジノ positions, number, and sizes of doors, and スポーツベット カジノ width and length of corridors are set. These are used to calculate entry and exit times, crowd size, and other information.

Development collaboration：Vector Research Institute,Inc/Algorithm Design Lab/ Institute of Technology

This system is based on a 3D model of スポーツベット カジノ finished surfaces of スポーツベット カジノ target space, such as スポーツベット カジノ walls, floor and ceiling. It predicts スポーツベット カジノ propagation of sound within スポーツベット カジノ space by tracking スポーツベット カジノ path of スポーツベット カジノ sound emitted from スポーツベット カジノ source on スポーツベット カジノ stage as it is transmitted and repeatedly reflected. スポーツベット カジノ materials and structure of each finished surface can be selected within スポーツベット カジノ tool. This allows Acoustic performance elements to be set, such as how much sound is absorbed when sound bounces off each surface.

Development collaboration： Institute of Technology

Time history response analysis can be performed by linking with スポーツベット カジノ batch processing function of SNAP (a structural analysis software for arbitrary shapes, Kozo System Inc.). スポーツベット カジノ obtained analysis results can also be processed and evaluated in Rhino.

Tools used: SNAP (Batch processing function)