se enseñan los principios de modelado básico y orgánico en Rhinoceros. En Grasshopper se estudian los principios de Parametrización, panelización y análisis en Grasshopper, así como el proceso de manufactura digital para maquinaria de corte Láser y CNC.
UN solo pago anticipado $5,000.00
Pagos diferidos $5,500.00*
*reserva tu lugar con el 50%
De lunes a viernes de 10 am a 18 pm
Del 23 al 27 de julio de 2012
DURACION: 40 HORAS
SESIONES: 5 DE 8 HORAS
o info@dimensiontallerdigital.com
informes al 55 (50 16 0634) con Mayri Gallegos (o al cel. 55 28 85 24 73)
Incluye material para corte digital.…
se will dramatically alter your creative process. This webinar will focus on creating algorithms using lists and transformations in Grasshopper, iteratively developing geometries inspired by nature. Through a series of short presentations and “live” case studies, learn strategies to discover forms that are defined by simple rules and incremental creation.
This webinar will last 2.5 hours including multiple open Q & A sessions. With two instructors offering guided curriculum and continuous support it is our goal to provide you with an in-depth and personal learning experience. A video of the webinar as well as instructor files will be uploaded after the broadcast – all participants will have unlimited access to the webinar content and this video online. Registration can be found below. We look forward to your participation!
Topics:
What’s an algorithm and how do I define one?
Isn’t Grasshopper already a “Graphical Algorithm Editor”? How is an Algorithmic Design different from Parametric Design?
What is the difference between incremental versus all-at-once execution? What creative opportunities does each provide?
I have a few simple transformations within my sketch. How can I compound them to discover new forms?
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e. I think I got the daylighting workflow, I have good background in daylighting simulations.
I have a question for you
Do you think daysim will be able to handle a Radiance material that has BTRD function, such as this one that I created using optics6
Here is an example material created by Optics 5
void glass Solarglaze 70 DS_glass003 0.670 0.713 0.688
void BRTDfunc Solarglaze 70 DS_front100.094 0.095 0.0930.615 0.654 0.6310 0 0.09 0 0 0 0 0 0 0 0 0
void BRTDfunc Solarglaze 70 DS_back100.104 0.105 0.1010.615 0.654 0.6310 0 0.09 0 0 0 0 0 0 0 0 0
I have another question, about the EC glazing, I would like to setup Honeybee so that when window surface temperature becomes larger than a specific value the glass changes to tinted one with low transmissivity , how do I go about that? can this be accomplished by setting up a schedule?
Thanks
Rania…
occur more than once in the same list, and different elements with identical values can occur more than once. Also, a list may contain lack of elements, referred to as "nulls".
Sets. Strictly speaking a Set is a mathematical construct which adheres to a strict collection of rules and limitations. Basically, a Set is the same as a List, with the exception that it cannot contain the same element more than once, or indeed two or more different elements with the same values. You see, in mathematics there is no difference between a value and an instance of that value, they are the same thing. In programming however it is possible to store the number 7 in more than one spot in the RAM. Grasshopper does not enforce this rule very strongly though, you can use a lot of Set components on lists that have multiple occurrences of the same value. The big difference between Lists and Sets in Grasshopper is that Sets are only defined for simple data types that have trivial equality comparisons. Basically: booleans, integers, numbers, complex numbers, strings, points, vectors, colours and intervals. Lists can contain all kinds of data.
Strings. Strings are text. There's nothing more to it. I don't know why early programmers chose to call them strings, but I suppose it's a better description of the memory representation of them. Strings are essentially sequences of individual characters.
Trees. Trees are the way all data is stored in Grasshopper. Even when you only have a single item, it will still be stored in a tree. A tree is a sorted collection of lists, where each list is identified by a path. A specific path can only occur once in a tree, when you merge two trees together, lists with identical paths are appended to each other. Trees are an attempt to losslessly represent not just the data itself, but also the history of that data. Imagine you have 4 curves {A,B,C,D} and you divide each into 3 points {X,Y,Z}. Then, for each of those points you create a new line segment {X',Y',Z'} and then divide each of those line segments again into 5 points each {K,L,M,N,O}. The way data is stored in trees, it should be possible to figure out whether a point M belongs to X' or to Z', and whether that X' or Z' came from A, B, C or D. This is why paths are often quite long after a while, because they encode a lot of history.
Paths. A Path is nothing more than a list of integers. It's denoted using curly brackets and semi-colons: {A;B;...;Z}. A Path should never be empty {} or have negative integers {0;-1}, but it is certainly possible to create a path like this and it probably won't even crash Grasshopper. Paths are 'grown' by components that (potentially) create more than one output value for a single input value. For example Divide Curve. It creates N points for every single input curve. In cases like this a new integer is appended to the end of the path.
In the next release the Path logic in Grasshopper is somewhat different. I fixed a number of obscure bugs (hopefully without introducing new fresh bugs) and special cased certain operations to somewhat reduce the speed at which paths grow. This may well break files that rely on a specific tree layout, but I hope the temporary sacrifice will be worth the long-term benefits.
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David Rutten
david@mcneel.com
Poprad, Slovakia…
t taking part at the Object office in Poznań.
The intention of this event is to provide a relaxed and flexible tutoring experience, with only one goal – getting to know Grasshopper better. We will start with a very exhaustive introduction, then venture into the computational geometry world in whichever direction we like.
Schedule
The long duration of the series (with a possibility of extension) will enable each participant to come up with their own research problems during the learning process. The scope of those problems will have a major influence in setting the direction of each workshop. While a couple of initial meetings will be solely spend on Grasshopper basics, the latter part of the series will have a more open character.
Each meeting day starts at 10 AM and lasts till 5 PM, with an hour long break for lunch (14 hours of tutoring per meeting).
Planned meetings:
02/03 Dec | Intro_01.gh: user interface, geometry types, Rhino/GH connection
16/17 Dec | Intro_02.gh: data flow, paneling, geometry rationalization
06/07 Jan | Intro_03.gh: data I/O, excel, csv, data visualization, preparing geometry for fabrication
20/21 Jan | Intro_04.gh: working with complex definitions, project organization and helpful plugins
10/11 Feb | Intro_05.gh: looping with Anemone, generative design
17/18 Feb | Intro_06.gh: automating tasks with Anemone, scripting introduction
03/04 Mar | Intro_07.gh: scripting
17/18 Mar | Intro_08.gh: Kangaroo
14/15 Apr | Intro_09.gh: user_defined_1 (flexible)
28/29 Apr | Intro_10.gh: user_defined_2 (flexible)
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nts for Ladybug too. They are based on PVWatts v1 online calculator, supporting crystalline silicon fixed tilt photovoltaics.
You can download them from here, or use the Update Ladbybug component instead. If you take the first option, after downloading check if .ghuser files are blocked (right click -> "Properties" and select "Unblock").
You can download the example files from here.
Video tutorials will follow in the coming period.
In the very essence these components help you answer the question: "How much energy can my roof, building facade, solar parking... generate if I would populate them with PV panels"?
They allow definition of different types of losses (snow, age, shading...) which may affect your PV system:
And can find its optimal tilt and orientation:
Or analyse its performance, energy value, consumption, emissions...
By Djordje Spasic and Jason Sensibaugh, with invaluable support of Dr. Frank Vignola, Dr. Jason M. Keith, Paul Gilman, Chris Mackey, Mostapha Sadeghipour Roudsari, Niraj Palsule, Joseph Cunningham and Christopher Weiss.
Thank you for reading, and hope you will enjoy using the components!
EDIT: From march 27 2017, Ladybug Photovoltaics components support thin-film modules as well.
References:
1) System losses:
PVWatts v5 Manual, Dobos, NREL, 2014
2) Sun postion equations by Michalsky (1988):
SAM Photovoltaic Model Technical Reference, Gilman, NREL, 2014
edited by Jason Sensibaugh
3) Angle of incidence for fixed arrays:
PVWatts Version 1 Technical Reference, Dobos, NREL, 2013
4) Plane-of-Array diffuse irradiance by Perez 1990 algorithm:
PVPMC Sandia National Laboratories
SAM Photovoltaic Model Technical Reference, Gilman, NREL, 2014
5) Sandia PV Array Performance Module Cover:
PVWatts Version 1 Technical Reference, Dobos, NREL, 2013
6) Sandia Thermal Model, Module Temperature and Cell Temperature Models:
Photovoltaic Array Performance Model, King, Boys, Kratochvill, Sandia National Laboratories, 2004
7) CEC Module Model: Maximum power voltage and Maximum power current from:
Exact analytical solutions of the parameters of real solar cells using Lambert W-function, Jain, Kapoor, Solar Energy Materials and Solar Cells, V81 2004, P269–277
8) PVFORM version 3.3 adapted Module and Inverter Models:
PVWatts Version 1 Technical Reference, Dobos, NREL, 2013
9) Sunpath diagram shading:
Using sun path charts to estimate the effects of shading on PV arrays, Frank Vignola, University of Oregon, 2004
Instruction manual for the Solar Pathfinder, Solar Pathfinder TM, 2008
10) Tilt and orientation factor:
Application for Purchased Systems Oregon Department of Energy
solmetric.com
11) Photovoltaics performance metrics:
Solar PV system performance assessment guideline, Honda, Lechner, Raju, Tolich, Mokri, San Jose state university, 2012
CACHE Modules on Energy in the Curriculum Solar Energy, Keith, Palsule, Mississippi State University
Inventory of Carbon & Energy (ICE) Version 2.0, Hammond, Jones, SERT University of Bath, 2011
The Energy Return on Energy Investment (EROI) of Photovoltaics: Methodology and Comparisons with Fossil Fuel Life Cycles, Raugei, Fullana-i-Palmer, Fthenakis, Elsevier Vol 45, Jun 2012
12) Calculating albedo: Metenorm 6 Handbook part II: Theory, Meteotest 2007
13) Magnetic declination:
Geomag 0.9.2015, Christopher Weiss…
flectance and use .2 as default. You can use ShadingProperty:Reflectance to change the default value. We don't support this in Honeybee interface right now but you can create the objects and add them to your energy model using additionalStrings_ input.
I put a simple example together were I change the reflection for shading surfaces to .5 for unglazed part of shading and portion and .7 for glazed part. I also set the percentage of glazing to 50% of the surface area.
I didn't put any input checks. Make sure to read the documentation to put valid input values for energyplus otherwise the energyplus simulation will fail. I also assumed that all the shading surfaces (context) will be planar surfaces.
Keep in mind that it will only effect the results if you are using one of the solar distributions with reflections. Honeybee is using FullInteriorAndExteriorWithReflections by default so you should be fine if you're using the default settings.
Hope it helps,
Mostapha
…
tema della modellazione parametrica con Grasshopper. Questa plug-in di Rhino consente di progettare, confrontandosi con un contesto evolutivo, attraverso la comprensione e l'utilizzo di parametri e componenti che influenzano la rappresentazione e la rendono dinamica componendo algoritmi. Nel corso verranno introdotte le nozioni base di Grasshopper approfondendo le metodologie della progettazione parametrica e le tecniche di modellazione algoritmica per la generazione di forme complesse.
Le informazioni teoriche saranno fornite in maniera accelerata ma organica e contestuale agli argomenti elencati. Per massimizzare i risultati, le lezioni saranno accompagnate da piccole esercitazioni pratiche.Argomenti trattati:- Introduzione alla progettazione parametrica: teoria, esempi, casi studio- Grasshopper: concetti base, logica algoritmica, interfaccia grafica- Nozioni fondamentali: componenti, connessioni, data flow- Funzioni matematiche e logiche, serie, gestione dei dati- Analisi e definizione di curve e superfici- Definizione di griglie e pattern complessi- Trasformazioni geometriche, paneling- Attrattori, image sampler- Data tree: gestione di dati complessiStrutturaIl corso ha una durata di 16 ore programmate nell'arco di 2 giornate con i seguenti orari: i giorni 10/11 e 11/11 dalle 10,00 alle 19,00 con pausa pranzo di un'ora.
PrerequisitiPer affrontare il corso è richiesta una conoscenza di base del software Rhino attraverso esperienze teoriche e pratiche. I partecipanti dovranno venire muniti di proprio laptop e con software Rhinoceros 5 o Rhinocero 4 perfettamente funzionanti.Alla fine del corso, verrà rilasciato l’attestato di partecipazione ad un corso qualificato certificato dalla McNeel, valido anche per l’ottenimento di crediti formativi universitari.
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es which you can see below in my mesh repair report I ran on the mesh after baking it.
This is a bad mesh.
Here is what is wrong with this mesh: Mesh has 2 non manifold edges. <<------because of the duplicate face Mesh has 1 duplicate face. Skipping face direction check because of positive non manifold edge count.
General information about this mesh: Mesh does not have any degenerate faces. Mesh does not have any extremely short edges. Mesh does not have any naked edges. Mesh does not have any self intersecting faces. Mesh does not have any disjoint pieces. Mesh does not have any unused vertices.
Continuing the repair process does rid the duplicate face. I also realized that rhino 5 has the command called "ExtractDuplicateMeshFaces" which works quite nicely.
However, this "method" is not available in rhinocommon currently. So I just wonder who can I ask to add it? It seems it would make sense to be in rhinocommon considering we have methods available for each of the other tests run by mesh repair. The reason I am interested in this command is it seems to work very fast.
Thanks
…
Added by Michael Pryor at 12:53am on December 11, 2014
tions or components.
Participants will learn concepts of object oriented programming and essential syntax of C# to endeavour into personally extending cad toolsets. The workshop will focus on introducing the .NET language C# and the Software Development Kit (SDK) RhinoCommon.
Topics
- use of Script Component within Grasshopper
- explanation to the .NET Framework
- introduction to RhinoCommon SDK
- basics of imperative / object-oriented programming
- data types, operators, properties
- variables, arrays, lists, enumerations
- methods
- objects, classes
- control structures: conditional statements (if, else, switch)
- control structures: loops (for, foreach, while, do)
- walk-through iterative und recursive code-samples
- use of RhinoCommon Geometry class library: creation, sorting, editing of Geometry (Points, Vectors, Curves, Surfaces)
- adding (baking) geometry to the active Rhino 3DM Document, including attributes (Name, Layer, Colors etc.)
- introduction to the Integrated Development Environment MS Visual Studio Express Edition
- compiling code to dll/gha files (plug-ins) / making your own Grasshopper custom components
Grasshopper wird auf der .NET Softwareplattform entwickelt, und kann ebenso wie das CAD Programm Rhinoceros mit "RhinoCommon", einem Software Development Kit, erweitert werden.
Dieser Kurs richtet sich an Designer, Architekten, Ingenieure und Techniker, welche mit dem grafischen Algorithmus-Modellierer "Grasshopper3d" sowie dem CAD-Programm "Rhinoceros" bereits vertraut sind und einen Einstieg in die Programmierung von Geometrie erlernen möchten.
Der Kurs Grasshopper II folgende Grundlagen:
Kennenlernen der Script Componente
Erläuterung zum .NET Framework
Einführung in RhinoCommon SDK
Grundlagen d. imperativen / objektorientierten Programmierung
Datentypen, Operatoren, Eigenschaften
Variablen, Reihen, Listen, Aufzählungen
Methoden
Objekte und Klassen
Kontrollstrukturen: Bedingte Ausführung, Schleifen
praxisnahe iterative und rekursive Code-Beispiele für generatives Design unter Verwendung der RhinoCommon Geometrie Klassenbibiliothek - Punkt- und Vektorgeometrie erstellen, sortieren, bearbeiten, Flächen und Netze erstellen - Geometrie in das Rhino 3DM Dokument baken, einschließlich Attribute (Name, Layer, Color)
Einführung in die Entwicklungsumgebung MS Visual Studio Express Edition
Kompilieren von Programmerweiterungen (plug-ins) als Komponenten (custom components)
Details, Anmeldung:
www.vhs-stuttgart.de
Trainer Peter Mehrtens
Kursdauer: 3 Tage x 8 h
Freitag, 21.02.2014, 9:00-17:00 Uhr Samstag, 22.02.2014, 9:00-17:00 Uhr Sonntag, 23.02.2014, 9:00-17:00 Uhr Ort: VHS Stuttgart, Fritz-Elsas-Str. 46/48
Teilnahmegebühr 510,00 €…