ou will see a list of potential matches, sorted from most relevant to least relevant:
Some components and objects support initialisation codes, which means you can assign certain values directly from the popup box. You can do this by adding an equals symbol after the name and then the value you wish to assign. For example, the [Curve Offset] component allows you to specify the offset distance via the popup box by typing =5 after the offset command:
However the popup box also supports a set of special formats that allow you to create specific objects without even typing their names. As of 0.9.0077 (which hasn't been released yet at the time of writing) you can use the following shortcuts to create special objects. In the notation below optional parts of a format will be surrounded by square brackets and hashes (#) will be used to indicate numeric values. So #,#[,#] means;
at least two numeric values separated by a comma, with an optional second comma and third number.
A complete list of special formats (not all of these are supported yet in 0.9.0076):
"∙∙∙ If the format starts with a double quote, then the entire contents (minus any other double quotes) will be placed into a Text Panel.
//∙∙∙ If the format starts with two forward slashes, then the entire contents will be placed in a Text Panel.
~∙∙∙ If the format starts with a tilde, then the entire contents will be placed in a Scribble object.
#,#[,#] If the format contains two or three numerics separated by commas, a Point parameter will be created with the specified coordinates.
+[#] If the format starts with a plus symbol followed by a numeric, then an Addition component will be created.
-[#] If the format starts with a minus symbol followed by a numeric, then a Subtraction component will be created.
*[#] If the format starts with an asterisk symbol followed by a numeric, then a Multiplication component will be created.
/[#] If the format starts with a forward slash symbol followed by a numeric, then a Division component will be created.
\[#] If the format starts with a backward slash symbol followed by a numeric, then an Integer Division component will be created.
%[#] If the format starts with a percent symbol followed by a numeric, then a Modulus component will be created.
&[∙∙∙] If the format starts with an ampersand symbol, then a Concatenation component will be created.
=[∙∙∙] If the format starts with an equals symbol, then an Equality component will be created.
<[*] If the format starts with a smaller than symbol, then a Smaller Than component will be created.
>[*] If the format starts with a larger than symbol, then a Larger Than component will be created.
[# *] Pi If the format contains the text "Pi" with an optional multiplication factor, then a Pi component will be created.
# If the format can be evaluated as a single numeric value, then a Slider will be created with the specified initial value and sensible™ lower and upper limits.
#<# If the format contains two numerics separated by a smaller than symbol, a Slider with the specified limits will be created. The initial slider value will be equal to the lower limit.
#<#<# If the format contains three numerics separated by a smaller than symbol, a Slider with the specified limits will be created. The initial slider value will be the value in the middle.
#..# If the format contains two numerics separated by two or more consecutive dots, a Slider with the specified limits will be created. The initial slider value will be equal to the lower limit.
#..#..# If the format contains three numerics separated by two or more consecutive dots, a Slider with the specified limits will be created. The initial slider value will be the value in the middle.
#/#/[#] If the format contains two or three numerics separated by forward slashes, a Calendar object will be created. The order of value is day/month/year. If year is omitted then the current year is used. Note that a second slash is required because #/# is interpreted as a number and thus results in a Slider.
#:#[:#] [am/pm] If the format contains at least two numerics separated by a colon, a Clock object is created. Seconds are optional, as are am/pm suffixes.
f([...[,...[,...]]]) [= *]If the format starts with a lower case f followed by an opening bracket, an Expression component is created. A list of comma separated arguments can be provided as inputs, and anything after the optional equals symbol becomes the expression string.
Note that decimal places will be harvested from formats that indicate sliders. I.e. the format 0..2..10 is not the same as 0..2..10.00, as the former will create an integer slider from zero to ten whereas the latter will create a floating point slider with two decimal places from zero to ten.…
Added by David Rutten at 3:24pm on February 18, 2013
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The problem is that using the index, adding a activies, the next activies change the index and then the link is wrong.
example: I need to connect to hotel function with house function, therefore i have 0 and 4 index in my panel.. So i have to extract the index linked to the alphabetical value to be able to draw lines between the points associated to the names of activities. Now if i add a new string between the values, the house activity hasn't the original index 4 but the new index 5. So the link will be not created between hotel and house but hotel e new activity in the index 4.
…
This is the actual reason I'm going through all this. I want to develop an algorithm that can be applied consistently and produce good results.
Here is a a little background. I'm working on my master's thesis in structural analysis. My thesis is on seismic behaviour of a roman temple in Portugal. I will be using a method of analysis suitable for block structures called the discrete element method. I am using a commercial code called 3DEC for this.
Now in order to the analysis I need to construct a 3D block model of my structure. I received a 3D scan of the entire structure (in *.wrl) format and spent a week trying to clean it up and slice it into the blocks that make up the structure. Now I want to use the scanned geometry of the blocks and describe a simplified prism around each that will represent the block in my analysis. I've attached a file with one of the columns in the temple. I think (at least with my tests so far) that it is representative of the all the blocks I'm dealing with.
Now my criteria for creation of the blocks:
I would like the contact area between the blocks to be as close as possible to the actual drum contact area,
I would like to get the volume of the blocks to be as close as possible (secondary to the contact area) to the volume of the actual drums in order to insure that the weight distribution in the structure is as close to reality as possible,
I would like the shape of the contact area to be as close to reality as possible
I order to satisfy all these requirements, I've done the following in my grasshopper file:
I take a section at the top and bottom of each of the drum meshes. I use this to extract the contact outline at the top and bottom of the drum. This is sometimes problematic and requires me to clean up the model and remove features that interfere.
Next I take each surface and try to fit a minimum circle around it. I try to do this because in my mind this is the best possible way to find the actual centre of the drum when there is cut outs and deterioration. This works well as long as more than half of the contact surface is still in its circular shape (third block from bottom in the example file doesn't satisfy this requirement and thus causes problems).
Knowing the centre, I use an algorithm I created in VB to search for one of the flutes on the contact profile. My ideas is that if I can find one of the flutes, I can then find the others by just going around at 30 degrees (there are 12 flutes) and find the location of all the flutes. In the VB code I've tried to explain my algorithm so I won't explain it here. I also think this algorithm is needlessly complicated and stupid as I'll explain later.
Once I've got one of the flutes, I just find the intersection of a line with at every 30 degrees with the outline curve.
Having all (12) points around the perimeter, I use an loop to scale the shape around the centre of the circle I found in step 1 to get the area within a tolerance value of the actual contact area (satisfying requirement 1). I was using HoopSnake before, but it required resetting every time so I decided to write my own thing.
I then connect the points on both top and bottom to get a solid block.
Now the problems are as follows:
Sometimes the algorithm doesn't find the best location as the starting point. As I said an important thing is that the circle is tangent to the flutes and that is true only if the column profile is larger than a half-circle.
The software I use requires convex blocks. I've tried to remedy this by using convex hull component before step 5 to insure the surfaces are convex.
I'm having issues sometimes with the alignment of top and bottom points. I think I just need to implement a component that sorts the points around a single basis so that there is no twisting.
I've been experimenting with convex hull as a general approach for defining the corner points, but I'm having problem take the convex hull curve and breaking it into a 12 sided polygon, preserving as much as possible the location of the flutes and the general shape of the contact surface.
I'm really sorry about the long post and complicated question. I hope someone can give some pointers on what I could try. I understand that this is not an easy question and that it is more a question of doing something rather than asking about grasshopper itself. My goal is to have an algorithm that I can explain as a general method for others to use in the future when dealing with these structures. This is only a small minor part of my thesis (the analysis is what is important) but it is taking a lot of time to figure out.
If you have any other questions, I would be more than happy to provide a better explanation. In the file I have created a region with all my input parameters. You can choose a different mesh from that point and change various settings. I hope that is self-explanatory.
Thanks for all your help,
Ali
BTW: I'm really sorry for the poor way I've done this stuff so far. I'm not a programmer and apart from some small macros in Excel I don't know much about this stuff. To add to that, I've just started with Rhino and Grasshopper about five days ago after almost pulling out all my hair trying to do this with AutoCAD!…
o my python component returning null despite running fine in the standalone python editor (i.e.: not through grasshopper).The original python script is as follows:
import randomimport rhinoscriptsyntax as rsrs.EnableRedraw(False)
def placeBuildings(curve, distance): pts=rs.DivideCurveLength(curve,5) counter=0 for myPoint in pts: counter=counter+1 #get the parmeter f current positision param=rs.CurveClosestPoint(curve,myPoint) #get teh tangent of this parameter tangent=rs.CurveTangent(curve,param) #calculate the angle of the tangent angle=rs.Angle((0,0,0),tangent) randomNumber=random.uniform(1,5) heightOfBuilding=random.uniform(4,40) rect=rs.AddRectangle(rs.WorldXYPlane(),randomNumber,2) rs.MoveObject(rect,(0,randomNumber,0)) hull=rs.ExtrudeCurveStraight(rect,(0,0,0),(0,0,heightOfBuilding)) rs.RotateObject(hull,(0,0,0),angle[0]) rs.MoveObject(hull,myPoint) #if counter%4: #rs.AddCircle(myPoint,3) #selection of curve#curveParameter=rs.GetCurveObject("sel curve")#curve=curveParameter[0]
curves=rs.GetCurveObject("select streets",4)distance=rs.GetInteger("distance?",4)for curve in curves: placeBuildings(curve,distance) rs.ReverseCurve(curve) placeBuildings(curve,distance)
When placed in grasshopper it is the following:
import randomimport rhinoscriptsyntax as rs
#randomNumber=random.uniform(1,5)#rs.AddCircle((0,randomNumber,0), 2)
def placeBuildings(curve, distance): pts=rs.DivideCurveLength(curve, 5) counter=0 for myPoint in pts: counter=counter+1 #get the parmeter f current positision param=rs.CurveClosestPoint(curve,myPoint) #get teh tangent of this parameter tangent=rs.CurveTangent(curve,param) #calculate the angle of the tangent angle=rs.Angle((0,0,0),tangent) randomNumber=random.uniform(1,5) heightOfBuilding=random.uniform(4,40) rect=rs.AddRectangle(rs.WorldXYPlane(),randomNumber,2) rs.MoveObject(rect,(0,randomNumber,0)) hull=rs.ExtrudeCurveStraight(rect,(0,0,0),(0,0,heightOfBuilding)) rs.RotateObject(hull,(0,0,0),angle[0]) rs.MoveObject(hull,myPoint)
#selection of curve#curveParameter=rs.GetCurveObject("sel curve")#curve=curveParameter[0]
curves=xdistance=y
for curve in curves: placeBuildings(curve,distance) rs.ReverseCurve(curve) placeBuildings(curve,distance)
I am unsure why there is no error being returned yet I cannot achieve any result other than null. Maybe someone could look at the script and tell me what is going wrong? I'm hoping to solve this before next Thursday so I might be asking for too much.
Much Appreciated.-A…
Added by Adem O'Byrne at 11:45am on October 9, 2014
What is it?Bumblebee is a set of user objects which connect Microsoft Excel and Grasshopper.
The current component set allows for not just the transfer of data back and forth between GH and XL but giv
t. So here we go!
1. Honeybee is brown and not yellow [stupid!]...
As you probably remember Honeybee logo was initially yellow because of my ignorance about Honeybees. With the help of our Honeybee expert, Michalina, now the color is corrected. I promised her to update everyone about this. Below are photos of her working on the honeybee logo and the results of her study.
If you think I'm exaggerating by calling her a honeybee expert you better watch this video:
Thank you Michalina for the great work! :). I corrected the colors. No yellow anymore. The only yellow arrows represent sun rays and not the honeybee!
2. Yellow or brown, W[here]TH Honeybee is?
I know. It has been a long time after I posted the initial video and it is not fun at all to wait for a long time. Here is the good news. If you are following the Facebook page you probably now that the Daylighting components are almost ready.
Couple of friends from Grasshopper community and RADIANCE community has been helping me with testing/debugging the components. I still think/hope to release the daylighting components at some point in January before Ladybug gets one year old.
There have been multiple changes. I finally feel that the current version of Honeybee is simple enough for non-expert users to start running initial studies and flexible enough for advanced users to run advanced studies. I will post a video soon and walk you through different components.
I think I still need more time to modify the energy simulation components so they are not going to be part of the next release. Unfortunately, there are so many ways to set up and run a wrong energy simulation and I really don’t want to add one new GIGO app to the world of simulation. We already have enough of that. Moreover I’m still not quite happy with the workflow. Please bear with me for few more months and then we can all celebrate!
I recently tested the idea of connecting Grasshopper to OpenStudio by using OpenStudio API successfully. If nothing else, I really want to release the EnergyPlus components so I can concentrate on Grasshopper > OpenStudio development which I personally think is the best approach.
3. What about wind analysis?
I have been asked multiple times that if Ladybug will have a component for wind study. The short answer is YES! I have been working with EFRI-PULSE project during the last year to develop a free and open source web-based CFD simulation platform for outdoor analysis.
We had a very good progress so far and our rockstar Stefan recently presented the results of the work at the American Physical Society’s 66th annual DFD meeting and the results looks pretty convincing in comparison to measured data. Here is an image from the presentation. All the credits go to Stefan Gracik and EFRI-PULSE project.
The project will go live at some point next year and after that I will release the Butterfly which will let you prepare the model for the CFD simulation and send it to EFRI-PULSE project. I haven’t tried to run the simulations locally yet but I’m considering that as a further development. Here is how the component and the logo looks like right now.
4. Teaching resources
It has been almost 11 months from the first public release of Ladybug. I know that I didn't do a good job in providing enough tutorials/teaching materials and I know that I won’t be able to put something comprehensive together soon.
Fortunately, ladybug has been flying in multiple schools during the last year. Several design, engineering and consultant firms are using it and it has been thought in several workshops. As I checked with multiple of you, almost everyone told me that they will be happy to share their teaching materials; hence I started the teaching resources page. Please share your materials on the page. They can be in any format and any language. Thanks in advance!
I hope you enjoyed/are enjoying/will enjoy the longest night of the year. Happy Yalda!
Cheers,
-Mostapha
…
rsistant data , as the inputs and outputs of the component should be build by the data stored in the object.
thanxs in advance
Michael
here is the code of the object....
public class Proxy { public List<string> _name_in; public List<string> _name_out; public List<SerializableType> _type_in; public List<SerializableType> _type_out; public List<GH_ParamAccess> _access_in; public string _path; public string _script; public bool _internalized; public bool _working; public Proxy(List<string> name_in, List<string> name_out, List<SerializableType> type_in, List<SerializableType> type_out, List<GH_ParamAccess> access_in, string path, string script, bool internalized) { _name_in = name_in; _name_out = name_out; _type_in = type_in; _type_out = type_out; _access_in = access_in; _path = path; _script = script; _internalized = internalized; _working = true; } public Proxy() { _name_in = new List<string>(); _name_out = new List<string>(); _type_in = new List<SerializableType>(); _type_out = new List<SerializableType>(); _access_in = new List<GH_ParamAccess>(); _path = get_path_of_plugin(); _script = ""; _internalized = false; _working = false; } public static string get_path_of_plugin() { string temp_cut; string string_path = System.Reflection.Assembly.GetExecutingAssembly().Location; string string_name = System.Reflection.Assembly.GetExecutingAssembly().GetName().Name; int temp_name_int = string_name.Length + 5; int temp_path_int = string_path.Length; temp_cut = string_path.Remove(temp_path_int - temp_name_int); return temp_cut; } public static T ObjectDeserializer<T>(string XmlInput) { System.Xml.XmlDocument XmlDoc = new System.Xml.XmlDocument(); XmlDoc.Load(new System.IO.StringReader(XmlInput)); System.Xml.Serialization.XmlSerializer ser = new System.Xml.Serialization.XmlSerializer(typeof(T)); T out_ob = (T)ser.Deserialize(new System.IO.StringReader(XmlInput)); return out_ob; } public static string ObjectSerializer<T>(T SerializedObject) { System.Xml.Serialization.XmlSerializer ser = new System.Xml.Serialization.XmlSerializer(typeof(T)); System.Text.StringBuilder builder = new System.Text.StringBuilder(); XmlWriter xmllol = XmlWriter.Create(builder); ser.Serialize(xmllol, SerializedObject); return builder.ToString(); } } public class SerializableType { private Type type; // when serializing, store as a string // [DataMember] public string TypeString { get { if (type == null) return null; return type.FullName; } set { if (value == null) type = null; else { type = Type.GetType(value); } } } public Type return_Type() { return type; } // constructors public SerializableType() { type = null; } public SerializableType(Type t) { type = t; } // allow SerializableType to implicitly be converted to and from System.Type static public implicit operator Type(SerializableType stype) { return stype.type; } static public implicit operator SerializableType(Type t) { return new SerializableType(t); } // overload the == and != operators public static bool operator ==(SerializableType a, SerializableType b) { // If both are null, or both are same instance, return true. if (System.Object.ReferenceEquals(a, b)) { return true; } // If one is null, but not both, return false. if (((object)a == null) || ((object)b == null)) { return false; } // Return true if the fields match: return a.type == b.type; } public static bool operator !=(SerializableType a, SerializableType b) { return !(a == b); } // we don't need to overload operators between SerializableType and System.Type because we already enabled them to implicitly convert public override int GetHashCode() { return type.GetHashCode(); } // overload the .Equals method public override bool Equals(System.Object obj) { // If parameter is null return false. if (obj == null) { return false; } // If parameter cannot be cast to SerializableType return false. SerializableType p = obj as SerializableType; if ((System.Object)p == null) { return false; } // Return true if the fields match: return (type == p.type); } public bool Equals(SerializableType p) { // If parameter is null return false: if ((object)p == null) { return false; } // Return true if the fields match: return (type == p.type); } } public class GH_Proxy : Grasshopper.Kernel.Types.GH_Goo<Proxy> { public override Grasshopper.Kernel.Types.IGH_Goo Duplicate() { return this; } public override bool IsValid { get { return true; } } public override string ToString() { return Proxy.ObjectSerializer<Proxy>(this.Value); } public override string TypeDescription { get { return "his is a proxy"; } } public override string TypeName { get { return "his is a proxy"; } } }…
ome work to create a ZScript macro for custom routines, but you can record those in ZBrush and then merely need to edit them into my script, inline, as bulk multiple-lines you just paste in, no problem as long as you strip the ZBrush button definition at the beginning.
ZBrush has a very high initial learning curve because of its non-standard interface. However, it has the world's most powerful quad remeshing and now mesh Booleans too. I needed a replacement for slow and especially non-robust marching cubes (Cocoon/Monolith/Dodo/Aether etc. on Grasshopper) that tended to bog down or blow up. IntraLattice was a step in a good direction but it can't merge fattened lines that merely cross each other with no breaks or that physically overlap on purpose to have many curve on in to a hub. But with $800 ZBrush 4R8, the latest version, that I can create English language ZScripts for, I suddenly have, often in the blink of an eye, or at worst a few seconds, right back into Rhino Grasshopper, a perfectly joined, airtight and smoothed mesh blending of upwards of thousands of input mesh pieces that overlap in ways Rhino will never Boolean union.
There is no complicated installation of anything since it's all done in Python.
The ZBrush program itself pops up while it works, and is then automatically backgrounded to bring you back to Grasshopper. It keeps running though, for fast iterations with no program startup time.
This is a general toolkit to expose myriad very advanced features of ZBrush into being just another Grasshopper plug-in like the rest.
It works by accepting a Grasshopper mesh and writing it to disk as an OBJ file, then incorporates ZBrush settings for a given command into a text format ZScript file, also written to disk from Python based on Grasshopper inputs, then ZBrush is told to run the script via Windows command line, and the exported OBJ output is read back from disk back into a Rhino Grasshopper mesh, in about a hundred lines of code.
Despite a change in mesh definition in Rhinocommon from version 5 to 6, I made it work on both versions.
So far this is only one command, the newly improved mesh Boolean union. It gives quad meshes, but they still look healthy when quickly triangulated in Rhino (as seen on top, above).
The ZBrush ZRemesher is utterly astounding in ability to transform any mesh into a direction following, error free quad mesh that can be converted to NURBS actually, via T-Splines smooth mode. That will be the next port to Grasshopper. I hope architects pick up on this more orderly manner of patterning surfaces than the alien slime of random point Voronoi.
Commercial software has the best code, not open source stuff, so far, so this is serious work to bring world class tools into Grasshopper where we can rapidly prototype computational strategies.
Here is a thread with several examples of ZBrush Boolean union remeshing applied to 3D trusses, compared to both IntraLattice and marching cubes:
http://www.grasshopper3d.com/forum/topics/custom-unit-cell-bug-in-intralattice-plug-in?commentId=2985220%3AComment%3A1828609
The same strategy of generating script files I used to port OpenFlipper, here, for triangle remeshing, which can now be combined with ZBrush Boolean unions of arbitrary assemblies of mesh units:
http://www.grasshopper3d.com/forum/topics/best-uniform-remesher-for-patterning-organic-suraces
UPDATE: I revamped the workflow so now components feed raw ZScript into a sequencer. Then only a single ZScript is assembled and sent to ZBrush so Python never gets ahead of ZBrush (!):
It is easy to DIY roll your own now:
…
Added by Nik Willmore at 6:48am on October 12, 2017