y from the Rhino model and having the absorption coefficients of the materials that are entered into Pachyderm, why is it not possible to generate a reverberation time diagram, without the need to start any analysis?
MAPPING METHOD: When for example the mapping of the Strenght Index (G) is generated through the "create map" option, succesively I can´t generate any other energy criterion map, but I have to redo the simulation.
Is it a limitation of the software or am I wrong something?
MAPPING METHOD: I kindly wanted to ask what is the difference between minimum and detailed convergence and why the number of reflections order it takes into account for the simulation is not specified. The mapping method take care only of the Raytracing Method or the Image Source too?
MAPPING METHOD: Why is the mapping value that can be exported to Rhino not generated for all the calculation raster points, but maximal only for 100 values?
MAPPING METHOD: This method hasn't been implemented in Grasshopper yet, has it?
RAYTRACING METHOD (Pach:RT): I did a raytracing through the components of GH, using only the Pach_RT, and I had these curious results in terms of time:
RaysCount: 15.000, IS_Order:1 = 5min
RaysCount: 15.000, IS_Order:2 = 12min
RaysCount: 15.000, IS_Order:3 = 3min
RaysCount: 15.000, IS_Order:4 = 8min
RaysCount: 15.000, IS_Order:5 = 3min
Why a raytracing with only 2 order, is more and more extensive than the 3/4 and 5 order?
ANALYSIS RESULT: Would there be a way to export all the results of a simulation, as is done via Odeon, to a .txt list?
I apologize in advance for asking so many questions, I hope you can find the time to answer,
Yours sincerely from Müller-BBM…
make quad mesh usable with Kangaroo and with limited inputs parameters in order to simulate funicular structures like "Vaulted Willow" or "Pleated Inflation" from Marc Fornes and the Verymany.
Here is a first attempt script.
As inputs there are :
Lines_in, just lines, no duplicates, on XY plane could have Z values, but the algorithm works on a , on XY plane could have Z values, but the algorithm works on a flat representation.
Tolerance is used to glue lines when points are closer than tolerance
Width is the half width of the “roads” going through the network
Angle is the shape of the ends of the roads, 0° means flat end, 180° a totally rounded end
Deviation is the shift generating spikes or enabling to generate pleated geometry
N_u is the number of subdivision along the “roads”, image above with 3 subdivisions on the roads
N_u is the number of subdivision across the “roads”
Zbool if false everything is flat, if true the mesh is in 3d, best with angle = 180° or -180°
For the outputs there is the topology of the network (like Sandbox)
As outputs geometry are put on datatree, each branch represent a path on the road, above 3 paths, which are brep output.
Adding a diagonal there are now 4 paths so 4 branches
The mesh M goes with F which are fixed points, anchor in Kangaroo.
U and V are lines in datatree, there will be used as spring in Kangaroo, U above
This script could be used to draw sort of roads, like in here https://codequotidien.wordpress.com/2013/03/22/hemfunction/
But the primary purpose is to do that.
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http://www.pilkington.com/) dominates the planar market. Charges "around" 1K Euros per m2 for a "plain" system. Personally in bespoke projects I design my own stuff but due to economies of scale ... they cost a bit more (but they look far more sexier, he he) . On the other hand only in a bespoke project I could dare to suggest such a solution (for a large scale building we are talking lots and lots of dollars).
3. Several scales below (aesthetics) you can find static alu systems (either structural or semi-structural):
Or hinged systems (either structural or semi-structural) capable to adapt in contemporary double curvature facades/roofs/envelopes/cats/dogs etc etc ... pioneered worldwide many years ago by my best friend Stefanos Tampakakis (everybody in UAE knows that genius man: http://www.alustet.gr/company.html):
4. With the exception of some paranoid things that Guru Stefanos does for Zaha these days we are talking about planar "facets" (obviously a triangle is such a planar facet). The current trend is: the more edges the better (humans excel in vanity matters). But achieving planarity in, say, quads (like yours) it adds another "restriction" on what you are doing. Until recently Evolute Tools Pro was the only answer. But right now ... well let's say that in short time you'll be greatly surprised by some WOW things in this Noble Forum, he he.
5. MERO (and obviously custom systems) can adapt (at almost no extra charge) in anything imaginable. But in a bespoke building ... well.. you know ultra rich people: they don't want MERO anymore since "everybody" does MERO solutions. Vanity, what else?
6. Smart Glass would become a must in the years to come: Eco-Architecture MUST dominate everything you do. On the other hand spending millions to do some extra WOW stuff (Vanity) ... it doesn't look to me very Eco-Friendly/Whatever ... but let's pretend so, he he.
7. I'm Architect but a bit different from the norm: for instance I smoke cigars (highly politically incorrect stuff) I always talk openly (ditto) and I ride lethal bikes (ditto).
may the Force (as always the Dark Option) be with you: go out there and kill them all.
best, Peter
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n fact) according a vast variety of "modes" PLUS the required clash detection (ALWAYS via trigonometry). In plain English: outline any collection of Breps and "apply" a truss that is topologically sound (planarization in case of quads etc is an added constrain). PLUS outline/solve what comes "next" after that truss (like the planar glazing "add-on" brackets of yours [ the ones that need redesign, he he], or some roofing/facade skin system [secondary supports, corrugated sheet metal, insulation, final cladding, dogs and cats])
2. Imaging doing this in real life (nothing to do with "abstract" formations of "lines" or "shapes" or whatever). This means primarily adopting a BIM umbrella: in plain English AECOSim, Revit or Allplan (I'm a Bentley man so I use AECOSim + Generative Components). This also means using "in-parallel" a top MCAD app for 1:1 details, FEA/FIM and the vast paraphernalia required for real-life studies destined for real-life projects (made with real-life money by real-life people). My choice: CATIA/Siemens NX.
3. What to send to Microstation (if not using Generative Components, that is) and/or CATIA? In what "state"? To do what exactly? For instance even if you could design this feature driven tensile membrane anchor custom node in Rhino (you can't) it could be 100% useless in CATIA:
4. Imaging masterminding ways to send them nested instance definitions of ... er ... a coordinate system (all what you need). In plain English: since is utterly pointless to send them nested blocks that can't been parametrically controlled (variations/modifications/PLM management/BOM/specs etc etc)... send them simply the "instructions" to place coordinate systems of components that ARE parametrically designed within Microstation and/or CATIA (classic feature driven design approach blah blah). So GH solves topology et all (working on data imported via, say, Excel sheets related with sizes of components etc etc) and sends to Microstation simply this (a myriad of "this" actually):
I do hope that the gist of the "method" (the ONLY way to invite GH to the party) is clear.
best, Peter…
Ladybug + Honeybee:
(Follow steps 0-4 for basic functionality and 0-9 for full functionality)
0. If you have an old version of LB+HB, download the file here (https://app.box.com/s/ds96em9l6stxpcw8kgtf)
and open it in Grasshopper to remove your old Ladybug and Honeybee version.
1. Make sure that you have a working copy of both Rhino and Grasshopper installed.
2. Open Rhino and type "Grasshopper" into the command line (without quotations). Wait for grasshopper to load.
3. Install GHPython 0.6.0.3 by downloading the file at this link (http://www.food4rhino.com/project/ghpython?ufh) and
drag the .gha file onto the Grasshopper canvas.
4. Select and drag all of the userObject files (downloaded with this instructions file) onto your Grasshopper canvas.
You should see Ladybug and Honeybee appear as tabs on the grasshopper tool bar.
(If you are reading this instruction on github you can download them from http://www.food4rhino.com/project/ladybug-honeybee)
5. Restart Rhino and Grasshopper. You now have a fully-functioning Ladybug. For Honeybee, continue to the following:
6. Install Radiance to C:\Radiance by downloading it from this link (https://github.com/NREL/Radiance/releases/download/4.2.2/radiance-4.2.2-win32.exe) and running the exe.
7. Install Daysim 4.0 for Windows to C:\DAYSIM by downloading it at this link (http://daysim.ning.com/page/download) and running the exe.
8. Install EnergyPlus 8.1 to C:\EnergyPlusV8-1-0 by going to the DOE website (http://apps1.eere.energy.gov/buildings/energyplus/energyplus_download.cfm), making an account, going to "download older
versions of EnergyPlus, selecting 8.1 and running the exe.
9. Copy falsecolor2.exe (http://pyrat.googlecode.com/files/falsecolor2.exe) and evalglare.exe (http://www.ise.fraunhofer.de/en/downloads-englisch/software/evalglare_windows.zip/at_download/file) to C:\Radiance\bin
10. You now have a fully-working version of Ladybug + Honeybee. Get started visualizing weather data with these video tutorials (https://www.youtube.com/playlist?list=PLruLh1AdY-Sj_XGz3kzHUoWmpWDXNep1O).
After I've done all the above I followed this video
https://vimeo.com/96155674
And everything works well.
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I tell you what I had to do and how I did it.
I have the following situation. A urban context with a square plot 40m x 40m surrounded by buildings.
If I extrude the plot I get 4 surfaces and I need to calculate the minimum daily quantity of direct sunlight hours each test point receives in the period from 22nd of April to 22nd of August. For example for the test point at index 21 of surface with index 1 (I am just creating these numbers in my mind) the minimum is on 27th of April and the test point receive 8 hours (this is also invented for the sake of the example) of direct sunlight. All the other days it receives more. So the values I have to found are these minimums for all the test points. Now how to calculate these minimum quantities is a different issue of the topic of this post and actually I manage it.
Continuing with the explanation of what I had to... so I have only the initial plot that generate 4 surfaces, then I want to test smaller plots generated by an offset of 4 m of the original one, and the relative 4 surfaces for each smaller plot.
So in this case I think I cannot use your suggestion because the object don't exist yet.
I managed creating a loop with Anemone, the loop generate an offset starting from the original at 0 until 4 (then I multiply it by 4 to obtain the offset at 0, 4, 8, 12 and 16. Then I did like you also suggest I record every time the result with the DataRecorder and I create for each result a different branch with the index coming from the loop (0, 1, 2, 3 and 4) with the Flatten component.
In this image you can see all the surfaces saved in the same way as described above and in white the test points that receive minmum or equal than 2.5 hours per day of direct sunlight in the period from from 22nd of April to 22nd of August and in dark gray the test points that receive less.
The main point of this discussion is just the fact that instead use this tricky way I used, or the one you suggest, to analyze separately (because they shade each other) 20 geometries (in this case 20 they could be many more) it would be good if it would be possible just to input all the geometries at the same time and they would not shade each other so to get directly all the results with one run and in a more simple way.
Francesco
…
requires four weather data inputs: air temperature (_dryBulbTemperature), relative humidity (relativeHumidity_), wind speed at 1.1 meters from the ground (windSpeed_) and mean radiant temperature (meanRadiantTemperature_).You can add values to the first three inputs from the Ladybug "Import Epw" component. For the last (meanRadiantTemperature_), you can add it from Ladybug's "Outdoor Solar Adjusted Temperature Calculator" component, or let "Thermal Comfort Index" component to calculate it. Both use different methods to calculate the final values.
I attached an example file below with second option.For more precise calculations you can use Honeybee and Chris' microclimate maps.An icing on the cake for the end: one of Ladybug developers yesterday released a set of Ladybug components for modelling in ENVI-met application. ENVI-met is cutting-edge microclimate software, which can be downloaded for free. It opens a number of advanced new analysis in outdoor domain, which couldn't have been done with the current Ladybug+Honeybee tools. So you can perform the simulation in ENVI-met 4 free software, and then add mean radiant temperature values from ENVI-met simulation to "Thermal Comfort Indices" component. Here is an example file.If you would like to go with the last approach, then the best would be to post a question about it in this topic.
1) You can make a polygonized tree.I haven't subtracted the trunk from the crown, but I guess it makes sense that it can be done.2) In most solar related simulations, a default albedo value of 0.2 is used. This corresponds to average albedo value taken from materials surrounding the urban or countryside location (concrete, grass, gravel, sand, asphalt...). However the presence of snow can significantly magnify the average albedo value several times. "Sunpath shading" components albedo_ input has an ability to calculate albedo due to presence of snow, if nothing is added to it (to albedo_ input). As you are performing the analysis of PET in a horizontal plane, it will not affect your calculations.3) Most thermal comfort indices will require performing analysis at 1.1 meters above the ground. This is considered to be height of standing person's gravity center.The same goes for PET index. So you are correct: you should place the analysis grid at 1.1 meters above the ground before adding it to the "Sunpath Shading" component.It is worth mentioning that "Thermal Comfort Indices" component used in this topic's PET_on_Grid2.gh and PET_on_Grid3.gh files is from last year, and much slower than the newest one (VER 0.0.64 MAR 18 2017) used in the example attached below. Just a remainder if you have been using older version of this component.Let me know if I misunderstood some of your questions, or if I missed to answer some of them.
EDIT: sorry for posting a double reply. When I posted it the first time, I only got links visible, with no text. Something has been wrong with grasshopper ning forum for the last couple of months.…
search for residential type and surprisingly there are none. This can be, but i'm surprised.
The location in example is the Financial District of Manhattan. I assume there might not be too many purely residential buildings there. If you increase the radius to 300meters it will find one.The OSMobject "Residential building" will look for mostly purely residential buildings. For example those in Chinatown or Lower East Side.However most of the time a building might be a multi-purpose: shops on the ground floor, offices above, and above them residential apartments. Users can sometimes avoid tagging these kind of buildings, and may just tag them with "buildings"="yes", not the type of the building too (for example: "building"="multiuse"). So this may be the problem why you might not get too many residential buildings.I guess the only solution to this issue is to add these tags by yourself. Then Gismo will instantly make use of them.I mentioned previously that I will create a couple of video tutorials, but I seemed to never found enough time. I apologize for that. The process is actually quite simple.
Here is small step by step tutorial on how to do that. It may take you about 2 minutes to tag your building and use that tag in Gismo.
Also office buildings. I imagine this is not up to you, but can be kind of disappointing. I wanted for example to do some Ladybug analysis only on residential or office buildings ... pitty.
"Office building" has not been added to "OSMobjects" dropdown list. I have just added it.However, whenever some sort of object is not defined in "OSMobjects" dropdown list, one can use the _requiredKey and requiredValues_ inputs of the "OSM tag" component:
I just tried looking for office building for the same location we have in the create_legend_example.gh file and it found 3 of them. There would probably need to be more, but it may be that nobody tagged those with "building"="office"
The legend is nice, though i think is not completely synchronized with the LegendBakeParameters: You need to provide a point for the LegenPlane input and another for the titleOriginPt output of the CreateLegend.
Unlike Ladybug, Gismo threats the title and the legend separately. So the legend's color bar would have its own starting point (plane) while the title will have its own. I found myself puzzled sometimes in Ladybug, why this wasn't possible.Or did I misunderstand you?…
Added by djordje to Gismo at 12:33pm on May 8, 2017
nted" in space (at instance definition creation phase): indicates the obvious fact that if garbage in > garbage out (try it).
2. Load the GH thing. Task for you: Using Named Views locate the points of interest as described further and make a suitable view. That way you can navigate rather easily around (hope dies last).
3. Your attractors are controlled from here:
The slider in blue picks some attractor to play with. You can use this while the K2 is running.
4. Don't change anything here (think of it as a black box: who cares how it works? nobody actually):
5. Enable the other "black box": job done your real-life stuff is placed:
6. Enable the solver: your "real-life" things start to bounce around:
7. Go there are play with the slider. A different attractor yields an other solution:
8. With real-life things in place if you disable the C# ... they are instantly deleted and you are back in lines/points and the likes:
9. Either with instance definitions or Lines/points change ... er ... hmm ... these "simple" parameters and discover the truth out there:
10. Since these are a "few" and they affect the simulation with a variety of ways ... we need a "self calibrating" system: some mini big Brother that does the job for us. Kinda like applying safely the brakes when it rains (I hate ABS mind).
NOTE: the rod with springs requires some additional code ,more (that deals with NESTED instance definitions) in order to (b) bounce as a whole and at the same time (b) elongates or shrinks a bit.
More soon.
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