ers can be applied from the right click Context Menu of either a component's input or output parameters. With the exception of <Principal> and <Degrees> they work exactly like their corresponding Grasshopper Component. When a I/O Modifier is applied to a parameter a visual Tag (icon) is displayed. If you hover over a Tag a tool tip will be displayed showing what it is and what it does.
The full list of these Tags:
1) Principal
An input with the Principal Icon is designated the principal input of a component for the purposes of path assignment.
For example:
2) Reverse
The Reverse I/O Modifier will reverse the order of a list (or lists in a multiple path structure)
3) Flatten
The Flatten I/O Modifier will reduce a multi-path tree down to a single list on the {0} path
4) Graft
The Graft I/O Modifier will create a new branch for each individual item in a list (or lists)
5) Simplify
The Simplify I/O Modifier will remove the overlap shared amongst all branches. [Note that a single branch does not share any overlap with anything else.]
6) Degrees
The Degrees Input Modifier indicates that the numbers received are actually measured in Degrees rather than Radians. Think of it more like a preference setting for each angle input on a Grasshopper Component that state you prefer to work in Degrees. There is no Output option as this is only available on Angle Inputs.
7) Expression
The Expression I/O Modifier allows you change the input value by evaluating an expression such as -x/2 which will have the input and make it negative. If you hover over the Tag a tool tip will be displayed with the expression. Since the release of GH version 0.9.0068 all I/O Expression Modifiers use "x" instead of the nickname of the parameter.
8) Reparameterize
The Reparameterize I/O Modifier will only work on lines, curves and surfaces forcing the domains of all geometry to the [0.0 to 1.0] range.
9) Invert
The Invert Input Modifier works in a similar way to a Not Gate in Boolean Logic negating the input. A good example of when to use this is on [Cull Pattern] where you wish to invert the logic to get the opposite results. There is no Output option as this is only available on Boolean Inputs.
…
ing the maps to the broader community.
At the moment, there are just a few known issues left that I have to fix for complex geometric cases but they should run smoothly for most energy models that you generate with Honeybee. Within the next month, I will be clearing up these last issues and, by the end of the month, there will be an updated youtube tutorial playlist on the comfort tools and how to use them.
In the meantime, there's an updated example file (http://hydrashare.github.io/hydra/viewer?owner=chriswmackey&fork=hydra_2&id=Indoor_Microclimate_Map) and I wanted to get you all excited with some images and animations coming out of the design part of my thesis. I also wanted to post some documentation of all of the previous research that has made these climate maps possible and give out some much deserved thanks. To begin, this image gives you a sense of how the thermal maps are made by integrating several streams of data for EnergyPlus:
(https://drive.google.com/file/d/0Bz2PwDvkjovJaTMtWDRHMExvLUk/view?usp=sharing)
To get you excited, this youtube playlist has a whole bunch of time-lapse thermal animations that a lot of you should enjoy:
https://www.youtube.com/playlist?list=PLruLh1AdY-Sj3ehUTSfKa1IHPSiuJU52A
To give a brief summary of what you are looking at in the playlist, there are two proposed designs for completely passive co-habitation spaces in New York and Los Angeles.
These diagrams explain the Los Angeles design:
(https://drive.google.com/file/d/0Bz2PwDvkjovJM0JkM0tLZ1kxUmc/view?usp=sharing)
And this video gives you and idea of how it thermally performs:
These diagrams explain the New York design:
(https://drive.google.com/file/d/0Bz2PwDvkjovJS1BZVVZiTWF4MXM/view?usp=sharing)
And this video shows you the thermal performance:
Now to credit all of the awesome people that have made the creation of these thermal maps possible:
1) As any HB user knows, the open source engines and libraries under the hood of HB are EnergyPlus and OpenStudio and the incredible thermal richness of these maps would not have been possible without these DoE teams creating such a robust modeler so a big credit is definitely due to them.
2) Many of the initial ideas for these thermal maps come from an MIT Masters thesis that was completed a few years ago by Amanda Webb called "cMap". Even though these cMaps were only taking into account surface temperature from E+, it was the viewing of her radiant temperature maps that initially touched-off the series of events that led to my thesis so a great credit is due to her. You can find her thesis here (http://dspace.mit.edu/handle/1721.1/72870).
3) Since the thesis of A. Webb, there were two key developments that made the high resolution of the current maps believable as a good approximation of the actual thermal environment of a building. The first is a PhD thesis by Alejandra Menchaca (also conducted here at MIT) that developed a computationally fast way of estimating sub-zone air temperature stratification. The method, which works simply by weighing the heat gain in a room against the incoming airflow was validated by many CFD simulations over the course of Alejandra's thesis. You can find here final thesis document here (http://dspace.mit.edu/handle/1721.1/74907).
4) The other main development since the A. Webb thesis that made the radiant map much more accurate is a fast means of estimating the radiant temperature increase felt by an occupant sitting in the sun. This method was developed by some awesome scientists at the UC Berkeley Center for the Built Environment (CBE) Including Tyler Hoyt, who has been particularly helpful to me by supporting the CBE's Github page. The original paper on this fast means of estimating the solar temperature delta can be found here (http://escholarship.org/uc/item/89m1h2dg) although they should have an official publication in a journal soon.
5) The ASHRAE comfort models under the hood of LB+HB all are derived from the javascript of the CBE comfort tool (http://smap.cbe.berkeley.edu/comforttool). A huge chunk of credit definitely goes to this group and I encourage any other researchers who are getting deep into comfort to check the code resources on their github page (https://github.com/CenterForTheBuiltEnvironment/comfort_tool).
6) And, last but not least, a huge share of credit is due to Mostapha and all members of the LB+HB community. It is because of resources and help that Mostapha initially gave me that I learned how to code in the first place and the knowledge of a community that would use the things that I developed was, by fa,r the biggest motivation throughout this thesis and all of my LB efforts.
Thank you all and stay awesome,
-Chris…
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Thanx……
ne – power of the many è un corso advanced level che studia la produzione di effetti complessi a partire dalla modellazione di comportamenti semplici su un insieme strutturato con un numero alto di elementi. Attraverso un approccio generico e scaleless sarà possibile affrontare la tematica generale su più fronti e in una molteplicità di declinazioni possibili. Il corso è rivolto a chi,indipendentemente dal proprio background (urbanistica, architettura, ingegneria, design, arte o altro) già possiede una esperienza di base con Rhinoceros e Grasshopper, e desidera sviluppare aspetti di gestione avanzata del flusso di articolato di informazioni attraverso una strategia guidata basata su esempi pratici e sull’implementazione di un progetto personale sul tema generale del “field behaviour”. Sarà trattato anche l’utilizzo di alcuni plug-ins quali gHowl e WeaverBird. Il numero dei partecipanti è fissato a un massimo di 20 per offrire un tutoraggio proficuo ed una effettiva esperienza di learning ad ogni iscritto.
[.] Temi:
teoria
. complessità, emergence, effetti di campo (field behaviour), sensibilità, efficienza multiperformance
tecnica
. dati:gestione e manipolazione avanzata del data tree, streaming e visualizzazione; transizione, blending e modulazione delle geometrie; generazione e controllo multiperformance di popolazioni di componenti; attrattori, drivers e tecniche di modulazione avanzate; uso delle mesh con WeaverBird; ottimizzazione con Galapagos
[.] Dettagli :
Tutors: Alessio Erioli + Andrea Graziano – Co-de-iT
Si richiede esperienza di base nella modellazione in Rhino (equivalente a Rhino training Level 1, il Level 2 è gradito – la documentazione per il training è disponibile gratuitamente all’indirizzo: http://download.rhino3d.com/download.asp?id=Rhino4Training&language=it) e nell’uso di Grasshopper (la suddivisione di una superficie NURBS in componenti tramite isotrim è data come base assodata)
. luogo:
IreCoop – via Vasco De Gama 27 _ Firenze
. durata:
25-27 febbraio 2010 – 3 giornate consecutive _ orario 9:00 – 18:00
. costo:
professionisti – 450.00 € studenti – 280.00 €
. note:
scadenza iscrizioni: 20 febbraio 2010 il corso sarà attivato con un numero minimo di 15 iscritti al termine sarà rilasciato un attestato di frequenza gli iscritti dovrano venire muniti dei propri laptop con software installato. una versione free per 30 giorni è disponibile sul sito www.rhino3d.com
. contatti:
iscrizioni + info alloggi: www.irecooptoscana.it (Cosa offriamo > formazione > altri corsi)
info sul corso: info@co-de-it.com…
rst option is the type of Point Grasshopper will display in the Rhino Viewport.
Dot
Point
Cross
Dot is a small dot of single colour.
Point is a slightly larger dot with a white center.
Cross an X-shaped cross. (Default)
Preview Plane Size
The option to change the size of the Plane appears as a fly out menu where an input box allows you to enter a value in Rhino Document Units to set the size of the Plane. (You must press Enter to accept the change)
Preview Mesh Edges
The option to hide/show mesh edges catches a few users out, thinking that the Meshing of the Object has failed.
And without...
There is a handy Shortcut of Ctrl+M to toggle between the two options.
Gumballs
As of version 0.9.0064, Grasshopper allows the user to move individual points that are Persistent[3a] by means of a Gumball in the Rhino Document. Volatile[3b] points can be made persistent by way of the Internalising feature found on the Context Menu of Components and Parameters
[3] Glossary:
Volatile - "liable to change rapidly and unpredictably". Referenced objects in Rhino are considered volatile.
Persistent - "continuing to exist or endure over a prolonged period". Internalised objects are considered persistent.
…
ust assume this is really what is being imported with the standard import line I see in all the examples:
# scriptcontext moduleimport RhinoPython.Host as __host'''The Active Rhino document (Rhino.RhinoDoc in RhinoCommon) while a scriptis executing. This variable is set by Rhino before the exection of every script.'''doc = None'''Identifies how the script is currently executing1 = running as standard python script2 = running inside grasshopper component3... potential other locations where script could be running'''id = 1'''A dictionary of values that can be reused between execution of scripts'''sticky = dict()def escape_test( throw_exception=True, reset=False ): "Tests to see if the user has pressed the escape key" rc = __host.EscapePressed(reset) if rc and throw_exception: raise Exception('escape key pressed') return rc def errorhandler(): ''' The default error handler called by functions in the rhinoscript package. If you want to have your own predefined function called instead of errorhandler, replace the scriptcontext.errorhandler value ''' return None…
Added by Nik Willmore at 7:47pm on October 10, 2015
eather data so it cannot be easily compared to Archsim. My account of the differences between Honeybee and Archsim will be far from complete but here are the key ones that I am aware of:
1) This difference is a bit of a superficial one but points to a deeper thinking about how the software should be used. Honeybee has many more components than Archsim, which means that Honeybee has a steeper learning curve than Archsim and will take longer to master. Along with this, you may also encounter a general mentality in the Honeybee community that "you should not be running a certain type of simulation unless you know how it works" whereas I know that Archsim is a bit more amenable to making things fast and easy to set up even when you are not sure what is going on under the hood. However, as a result of the large number of components in Honeybee, it is more open-ended, customizable, and includes more freedom in terms of cases that you can run and the parameters of the energy simulation that you can change than Archsim. You will also notice that, while there is a general ethos in the Honeybee community that you should not be running certain simulations unless you know what you are doing, we try to provide you with many resources to educate yourself if you are motivated. For example, we have long component descriptions that we assemble into documentation books like this (https://www.gitbook.com/book/mostapharoudsari/honeybee-primer/details), hours of video tutorial playlist like this one (https://www.youtube.com/playlist?list=PLruLh1AdY-SgW4uDtNSMLeiUmA8YXEHT_), and many GH example files on a github-based file sharing system (https://hydrashare.github.io/hydra/index.html). Not to mention a community of people who would respond to discussions like this one.
2) Archsim as a standalone application will soon be no more and will be instead distributed with the DIVA daylight analysis tool (http://diva4rhino.com/). While I am unclear on the exact trajectory of DIVA, it currently has a price tag attached to it and so I would assume that the future of Archsim will also carry this price tag. On the other hand, Honeybee and any derivative software will forever be free and open source under the GPL licence (https://github.com/mostaphaRoudsari/Honeybee/blob/master/License_Honeybee_GPL.txt).
3) This third point is a bit of a reiteration of the last one but Honeybee is open source, meaning that, if you need a feature of EnergyPlus that is not yet implemented on either interface, you can usually add it in yourself with a few lines of python code in Honeybee. This type of workflow is not possible with Archsim since it is closed source and requires you to use EnergyPlus's text editor interface after Archsim has exported an IDF in order to implement any additional EnerygPlus features.
4) The libraries and templates for Honeybee come from OpenStudio - the open source interface for EnergyPlus (https://www.openstudio.net/), which is supported by the US Department of Energy (just like EnergyPlus). Since Honeybee is open source, it is able to make use of the large database of building type schedules/loads and constructions that have been assembled by the OpenStudio team over the last several years as well as OpenStudio's SDK. I can also say that almost all of the development efforts of the Honeybee team are now focused now on integrating efforts with OpenStudio, including an exporter from Honeybee to OpenStudio that should be fully functional for the next stable release. I am not certain of the current extent of Archsim's libraries but, last I had checked, the creator was pulling them from his own experience and, as such, only had a few libraries to choose from. For all of my knowledge, through, this may be changing with the integration of Archsim with DIVA.
Let me know if this is helpful and, if anyone has more up-to-date knowledge on Archsim than I, please post there.
-Chris…
ave pointed out, if the older version of Honeybee EPZone does not have the recirculatedAirPerArea proprety, then it must be the cause of the error as I am using the Honeybee_Export to OpenStudio component (VER 0.0.58 Nov_07_2015). Given the discrepancy between the version of the Honeybee components used to setup everything in the file all the way prior to the point feeding the zones' data into the Export to Open Studio component, I can see different options/questions to tackle this issue:
1- I have the OpenStudio 1.9.0 that works with EnergyPlusV8-3-0 installed on my computer and the reason that I had to use the newer version of the Honeybee_Export to OpenStudio component (VER 0.0.58 Nov_07_2015) is that I had initially received an error message using the component of the same version as consistent with the rest of the project (VER 0.0.57 Jul_15_2015) with the following content:
"Cannot find OpenStudio libraries. You can download the libraries from the link below. Unzip the file and copy it to C:\Users\Alireza\AppData\Roaming\Ladybug\OpenStudio and try again. Click on the link to copy the address.https://app.box.com/s/y2sx16k98g1lfd3r47zi"
The download link provided in the error message appears to be not active and thereby, I could not follow the instructions on the error message and make the Hoenybee_Export to OpenStudio component (VER 0.0.57 Jul_15_2015) work.
Therefore, if there is a way to make this version (VER 0.0.57 Jul_15_2015) of the Hoenybee_Export to OpenStudio component work by downloading the OpenStudio libraries or switching to a legacy version of the OpenStudio application prior to 1-9-0, then probably this would be one option to solve this issue.
2- When I realized I could not download the OpenStudio libraries as described in section 1 (see above) and make the Honeybee_Export to OpenStudio Component (VER 0.0.57 Jul_15_2015) work with the installed OpenStudio application (V1-9-0), I updated the entire installation of Ladybug + Honeybee User Object files to the new version (Ladybug_0_0_61 and Honeybee_0_0_58). This time the Honeybee_Export to OpenStudio component (VER 0.0.58 Nov_07_2015) seemed to be working with the installed OpenStudio application (V1-9-0) as I did not receive any error messages about missing OS libraries. However, I could not make things work since all other components in my project (eg. Creat HB Zones,Creat HB Surface) have been setup with the 0.0.57 version and obviously, the updated version of the Honeybee User Objects (V0.0.58) could not recognize my HB component of the previous version in the file.
If there is a way to make 'in-place' updates of HB components, for example updating the Honeybee_Create HB Zones in the file without having to re-wire everything from scratch, then it probably would work as the updated version will include the 'recirculatedAirPerArea' property. Otherwise, given the complexity of the scene, it appears to be impossible for me to start everything from scratch and setup the entire scene with the new version of HB components.
3- If none of the options in the last two sections (see above) would be possible, I was wondering if there is a way to open the zones' data as the outcome of the Honeybee_Solve Adjacency component (prior to feeding this data to the Honeybee_Open Studio Systems component and subsequently, to the the Hoenybee_Export to Open Studio) in a text-editor and manually add the missing recirculatedAirPerArea property to the zones' data; then probably I could do that and then eventually feed it to the Hoenybee_Export to Open Studio component.
These are the three options that I could think of in order to tackle this issue of mine. I apologize for the extended reply but I figured it would be better to give a more comprehensive description of my problem and previous attempts to solve it.
Any helps is most appreciated.
Please let me know if you need further information about the described issues in each section or the simulation scene setup in general.
Thank you,
Alireza
…
n the z axis I can not, here's the problem, because the movement is not only on the z axis, I can't do a serie with this vector. I tried to do it by differents columns or rows but its impossible for me.
2. Another problem. How I can fill a surface like this with tetrahedrons? What about change the size of this tetrahedrons? Is it possible like a fractal? :Si'm still working...
Thank you!
Finally I have completed the cloud!! I am a little bit fool. With the help of some sketches it was not so difficult! :).
I found the movement pattern of my tetrahedrons
Then I found the points inside my surface!
But now I cant create lines between points like in the begining of the process, with the pattern with points 1, 2, 3, 4. What I have to do?
??????????
Bye!!!…
er). With the command "End Bulge" I noticed that G2 moves perpendicular to G1! But with an increase which is not equal... and is different, every time, depending on the angle between G0 and G1 and G2. How do I predict the position of G2 compared to G1 simulating the "End Bulge" command? Thank you for your professional answers.
^___^
Below you can see an example with a curve crimson ... If I move G1 of 1 unit G2 moves of 0.42 units (perpendicular) .. If I move of 2 units the next step is 0.46 unit... 3 units --> step 0,50 units... etc.
And each time changes depending on the initial conditions (G0/G1/G2 angle).
…
Added by Lucius Santo at 4:21pm on September 20, 2012