into curves, and so I would like to use within Grasshopper.
I would really appreciate if anyone well versed in RhinoScript/VB.Net Syntax would be kind enough to help out.
Thank you for reading this.
' ConvertTextToGeometry.rvb -- September 2008
' If this code works, it was written by Dale Fugier.
' If not, I don't know who wrote it. ' Works with Rhino 4.0.
Option Explicit
Sub ConvertTextToGeometry
' Declare local variables
Dim obj_list, obj, saved_plane, cmd
Dim font, height, plane, style, text, bold, italic
' Select annotation objects
obj_list = Rhino.GetObjects("Select text to convert to geometry", 512, True, True)
If Not IsArray(obj_list) Then Exit Sub
' For speed, turn of screen redrawing
Call Rhino.EnableRedraw(False)
' Save the current construction plane
saved_plane = Rhino.ViewCPlane()
' Process each selected object
For Each obj In obj_list
' Weed out just the text objects
If Rhino.IsText(obj) Then
' Acquire the text parameters
font = "<single_stroke_font_name>"
height = Rhino.TextObjectHeight(obj)
plane = Rhino.TextObjectPlane(obj)
style = Rhino.TextObjectStyle(obj)
text = Rhino.TextObjectText(obj)
If (style And 1) Then
bold = "_Yes"
Else
bold = "_No"
End If
If (style And 2) Then
italic = "_Yes"
Else
italic = "_No"
End If
' Set the current construction plane
Call Rhino.ViewCPlane(, plane)
' Add a new text object (geometry)
cmd = "_-TextObject "
cmd = cmd & "_GroupOutput=_Yes "
cmd = cmd & "_FontName=" & font & " "
cmd = cmd & "_Italic=" & italic & " "
cmd = cmd & "_Bold=" & bold & " "
cmd = cmd & "_Height=" & CStr(height) & " "
cmd = cmd & "_Output=_Curves "
cmd = cmd & "_AllowOpenCurves=_Yes "
cmd = cmd & Chr(34) & text & Chr(34) & " "
cmd = cmd & "0"
Call Rhino.Command(cmd, 0)
' Delete the original object
Call Rhino.DeleteObject(obj)
End If
Next
' Restore the saved construction plane
Call Rhino.ViewCPlane(, saved_plane)
' Enable screen redrawing
Call Rhino.EnableRedraw(True)
End Sub
…
lly it should not make much of a difference - random number generation is not affected, mutation also is not. crossover is a bit more tricky, I use Simulated Binary Crossover (SBX-20) which was introduced already in 1194:
Deb K., Agrawal R. B.: Simulated Binary Crossover for Continuous Search Space, inIITK/ME/SMD-94027, Convenor, Technical Reports, Indian Institue of Technology, Kanpur, India,November 1994
Abst ract. The success of binary-coded gene t ic algorithms (GA s) inproblems having discrete sear ch sp ace largely depends on the codingused to represent the prob lem variables and on the crossover ope ratorthat propagates buildin g blocks from pare nt strings to childrenst rings . In solving optimization problems having continuous searchspace, binary-co ded GAs discr et ize the search space by using a codingof the problem var iables in binary st rings. However , t he coding of realvaluedvari ables in finit e-length st rings causes a number of difficulties:inability to achieve arbit rary pr ecision in the obtained solution , fixedmapping of problem var iab les, inh eren t Hamming cliff problem associatedwit h binary coding, and processing of Holland 's schemata incont inuous search space. Although a number of real-coded GAs aredevelop ed to solve optimization problems having a cont inuous searchspace, the search powers of these crossover operators are not adequate .In t his paper , t he search power of a crossover operator is defined int erms of the probability of creating an arbitrary child solut ion froma given pair of parent solutions . Motivated by t he success of binarycodedGAs in discret e search space problems , we develop a real-codedcrossover (which we call the simulated binar y crossover , or SBX) operatorwhose search power is similar to that of the single-point crossoverused in binary-coded GAs . Simulation results on a number of realvaluedt est problems of varying difficulty and dimensionality suggestt hat the real-cod ed GAs with t he SBX operator ar e ab le to perform asgood or bet t er than binary-cod ed GAs wit h t he single-po int crossover.SBX is found to be particularly useful in problems having mult ip le optimalsolutions with a narrow global basin an d in prob lems where thelower and upper bo unds of the global optimum are not known a priori.Further , a simulation on a two-var iable blocked function showsthat the real-coded GA with SBX work s as suggested by Goldberg
and in most cases t he performance of real-coded GA with SBX is similarto that of binary GAs with a single-point crossover. Based onth ese encouraging results, this paper suggests a number of extensionsto the present study.
7. ConclusionsIn this paper, a real-coded crossover operator has been develop ed bas ed ont he search characte rist ics of a single-point crossover used in binary -codedGAs. In ord er to define the search power of a crossover operator, a spreadfactor has been introduced as the ratio of the absolute differences of thechildren points to that of the parent points. Thereaft er , the probabilityof creat ing a child point for two given parent points has been derived forthe single-point crossover. Motivat ed by the success of binary-coded GAsin problems wit h discrete sear ch space, a simul ated bin ary crossover (SBX)operator has been develop ed to solve problems having cont inuous searchspace. The SBX operator has search power similar to that of the single-po intcrossover.On a number of t est fun ctions, including De Jong's five te st fun ct ions, ithas been found that real-coded GAs with the SBX operator can overcome anumb er of difficult ies inherent with binary-coded GAs in solving cont inuoussearch space problems-Hamming cliff problem, arbitrary pr ecision problem,and fixed mapped coding problem. In the comparison of real-coded GAs wit ha SBX operator and binary-coded GAs with a single-point crossover ope rat or ,it has been observed that the performance of the former is better than thelatt er on continuous functions and the performance of the former is similarto the lat ter in solving discret e and difficult functions. In comparison withanother real-coded crossover operator (i.e. , BLX-0 .5) suggested elsewhere ,SBX performs better in difficult test functions. It has also been observedthat SBX is particularly useful in problems where the bounds of the optimum
point is not known a priori and wher e there are multi ple optima, of whichone is global.Real-coded GAs wit h t he SBX op erator have also been tried in solvinga two-variab le blocked function (the concept of blocked fun ctions was introducedin [10]). Blocked fun ct ions are difficult for real-coded GAs , becauselocal optimal points block t he progress of search to continue towards t heglobal optimal point . The simulat ion results on t he two-var iable blockedfunction have shown that in most occasions , the sea rch proceeds the way aspr edicted in [10]. Most importantly, it has been observed that the real-codedGAs wit h SBX work similar to that of t he binary-coded GAs wit h single-pointcrossover in overcoming t he barrier of the local peaks and converging to t heglobal bas in. However , it is premature to conclude whether real-coded GAswit h SBX op erator can overcome t he local barriers in higher-dimensionalblocked fun ct ions.These results are encour aging and suggest avenues for further research.Because the SBX ope rat or uses a probability distribut ion for choosing a childpo int , the real-coded GAs wit h SBX are one st ep ahead of the binary-codedGAs in te rms of ach ieving a convergence proof for GAs. With a direct probabilist ic relationship between children and parent points used in t his paper,cues from t he clas sical stochast ic optimization methods can be borrowed toachieve a convergence proof of GAs , or a much closer tie between the classicaloptimization methods and GAs is on t he horizon.
In short, according to the authors my SBX operator using real gene values is as good as older ones specially designed for discrete searches, and better in continuous searches. SBX as far as i know meanwhile is a standard general crossover operator.
But:
- there might be better ones out there i just havent seen yet. please tell me.
- besides tournament selection and mutation, crossover is just one part of the breeding pipeline. also there is the elite management for MOEA which is AT LEAST as important as the breeding itself.
- depending on the problem, there are almost always better specific ways of how to code the mutation and the crossover operators. but octopus is meant to keep it general for the moment - maybe there's a way for an interface to code those things yourself..!?
2) elite size = SPEA-2 archive size, yes. the rate depends on your convergence behaviour i would say. i usually start off with at least half the size of the population, but mostly the same size (as it is hard-coded in the new version, i just realize) is big enough.
4) the non-dominated front is always put into the archive first. if the archive size is exceeded, the least important individual (the significant strategy in SPEA-2) are truncated one by one until the size is reached. if it is smaller, the fittest dominated individuals are put into the elite. the latter happens in the beginning of the run, when the front wasn't discovered well yet.
3) yes it is. this is a custom implementation i figured out myself. however i'm close to have the HypE algorithm working in the new version, which natively has got the possibility to articulate perference relations on sets of solutions.
…
e chosen to dive into Grasshopper. I’m about 6 months in. If some of my comments are completely off, please take that to mean that a feature is too inaccessible to a newish user rather that it’s just missing, as I may have stated.
One of my primary pain points is this. Things that can be done in other programs are invariably easier in other programs. This is a big enough issue that I doubt there’s an easy solution that an armchair qb like myself can offer up.
The interface:
I’ve used a lot of 3D programs. I’ve never encountered one as difficult as grasshopper. What in other programs is a dialog box, is 8 or 10 components strung together in grasshopper. The wisdom for this I often hear among the grasshopper community is that this allows for parametric design. Yet PTC (Parametric Technology Corp.) has been doing parametric design software since 1985 and has a far cleaner and more intuitive interface. So does SolidWorks, Inventor, CATIA, NX, and a bunch of others.
In the early 2000's, when parametric design software was all the rage, McNeel stated quite strongly the Rhino would remain a direct modeler and would not become a parametric modeler. Trends come. Trends go. And the industry has been swinging back to direct modeling. So McNeel’s decision was probably ok. But I have to wonder if part of McNeel’s reluctance to incorporate some of the tried and proven ideas of other parametric packages doesn't have roots in their earlier declaration to not incorporate parametrics.
A Visual Programming Language:
I read a lot about the awesomeness and flexibility of Grasshopper being a visual programming language. Let’s be clear, this is DOS era speak. I believe GH should continue to have the ability to be extended and massaged with code, as most design programs do. But as long as this is front and center, GH will remain out of reach to the average designer.
Context sensitivity:
There is no reason a program in 2014 should allow me to make decisions that will not work. For example, if a component input is in all cases incompatible with another component's output, I shouldn't be able to connect them.
Sliders:
I hate sliders. I understand them, but I hate ‘em. I think they should be optional. Ya, I know I can r-click on the N of a component and set the integer. It’s a pain, and it gives no feedback. The “N” should turn into the number if set. AAAnd, sliders should be context sensitive. I like that the name of a slider changes when I plug it into something. But if I plug it into something that'll only accept a 1, a 2, or a 3, that slider should self set accordingly. I shouldn't be able to plug in a “50” and have everything after turn red.
Components:
Give components a little “+” or a drawer on the bottom or something that by clicking, opens the component into something akin to a dialog box. This should give access to all of the variables in the component. I shouldn't have to r-click on each thing on a component to do all of the settings.
And this item I’m guessing on. I’m not yet good enough at GH to know if this may have adverse effects. Reverse, Flatten, Graft, etc.; could these be context sensitive? Could some of these items disappear if they are contextually inappropriate or gray out if they're unlikely?
Tighter integration with Rhino:
I'm not entirely certain what this would look like. Currently my work flow entails baking, making a few Rhino edits, and reinserting into GH. I question the whole baking thing, btw. Why isn't it just live geometry? That’s how other parametric apps work. Maybe add more Rhino functionality to GH. GH has no 3D offset. I have to bake, offsetserf, and reinsert the geometry. I’m currently looking at the “Geometry Cache” and “Geometry Pipeline” components to see if they help. But I haven't been able to figure it out. Which leads me to:
Update all of the documentation:
I'm guessing this is an in process thing and you're working toward rolling GH from 0.9.00075 to 1.0. GH was being updated nearly weekly earlier this year. Then it suddenly stopped. If we're talking weeks before a full release, so be it. But if we're looking at something longer, a documentation update would help a lot. Geometry Cache and Geometry Pipeline’s help still read “This is the autogenerated help topic for this object. Developers: override the HtmlHelp_Source() function in the base class to provide custom help.” This does not help. And the Grasshopper Primer 2nd Ed. was written for GH 0.60007.
Grasshopper is fundamentally a 2D program:
I know you'll disagree completely, but I'm sticking to this. How else could an omission like offsetsurf happen? Pretty much every 3D program in existence has this. I’m sure I can probably figure out how to deconstruct the breps, join the curves, loft, trim, and so forth. But does writing an algorithm to do what all other 3D programs do with a dialog box seem reasonable? I'm sure if you go command by command you'll find a ton on such things.
If you look at the vast majority of things done in GH, you'll note that they're mostly either flat or a fundamentally 2D pattern on a warped surface.
I've been working on a part that is a 3D voronoi trimmed to a 3D model. I've been trying to turn the trimmed voronoi into legitimate geometry for over a month without success.
http://www.grasshopper3d.com/profiles/blogs/question-voronoi-3d-continued
I’ve researched it enough to have found many others have had the exact same problem and have not solved it. It’s really not that conceptually difficult. But GH lacks the tools.
Make screen organization easier:
I have a touch of OCD, and I like my GH layout to flow neatly. Allow input/output nodes to be re-ordered. This will allow a reduction in crossed wires. Make the wire positions a bit more editable. I sometimes use a geometry component as a wire anchor to clean things up. Being able to grab a wire and pull it out of the way would be kinda nice.
I think GH has some awesome abilities. I also think accessing those abilities could be significantly easier.
~p…
re are major changes and enhancements.
HONEYBEE
More Flexible Workflow - Many small modifications were made to support a more flexible workflow, such as the ability to separate a zone created with masses2Zones into editable HBSrfs that can be recombined. For the energy components, it is now possible to plug custom constructions directly into the components that set the zone constructions without writing them first into the library. For the daylighting components it is now possible to change all of the materials of specific surface types at once.
Support for Complex Geometry - Many small bugs for complex geometry have been fixed including the ability to import energy results correctly for curved NURBS surfaces as well as unconventional window configurations. Also, the intersectMasses component now almost always succeeds in splitting all of the surfaces of adjacent zones, no matter how complex the intersection is.
Automatic Download Issues Fixed - Many users who faced issues with not having “gendaymtx.exe” or who had trouble syncing with our github know that we faced an issue with automatic background downloads.
Air Walls - Honeybee EnergyPlus models now officially support air walls (or virtual partitions) in a basic implementation. Now, any time that you use the air wall construction or set a surface type to “air wall,” the air between adjacent zones will be automatically mixed. At present, this mixing is just a constant flow based on the surface area between zones connected by air walls multiplied by an adjustable “flow factor.” It is important to stress that this basic air mixing is not with the EnergyPlus Airflow Network, although the groundwork laid in this release will eventually allow for the implementation of the Airflow Network in future releases. As such, this present air mixing is only suitable for multi-zone conditions where there is not significant buoyancy-driven flow between zones.
Natural Ventilation - To go along with the new potential introduced by air walls, there has been a basic implementation of EnergyPlus’s natural ventilation objects in a new component called “Set EP Airflow”. The current setup allows for three possible types of natural ventilation: 1) natural ventilation through windows (with auto-calculated flow based on window area, outdoor wind speed/direction, and stack effects), 2) custom wind and stack objects that can be used to model things such as chimneys off of single zones, and 3) constant, fan-driven natural ventilation.
Additional Thermal Mass - The capability to add additional thermal mass to zones has been added. This is useful for factoring in the mass of indoor furniture or heavy interior objects such as chimneys.
New Utility Components - Abraham has added a couple of useful components to help calculate lighting loads based on bulb types and target lighting levels as well as a converter from ACH to the m3/s-m2 that the other HB components accept. Along this vein, there is also a component for adding in the resistance of Air Films to HB constructions.
Improved and Editable Ideal Air Loads System - The EnergyPlus Ideal Air System now goes through an automatic sizing period at the start of the simulation based on the extreme weeks of the weather file. Furthermore, the ability to adjust many of the parameters of the ideal air loads system have been added with a new “Set Ideal Air Loads Parameters” component. The component allows you to add in heat recovery, air side economizers and demand-controlled ventilation.
OpenStudio Export Update - The OpenStudio workflow is still largely under development but this release includes a version with a working VAV and PTHP system template for those curious with experimenting. Note that not all of the new features available for the basic “Run Energy Simulation” component are available for the OpenStudio component (such as air walls, natural ventilation, or additional thermal mass).
Microclimate/Indoor Comfort Maps - Blossoming from initial experiments with the radiant temperature map, a workflow for looking into sub-zone microclimate and indoor comfort has been initiated. All components for this are presently under the Honeybee WIP tab but, over the next month, they will be completing their development phase and moving into the rest of the tabs. If you are interested in testing when they are ready, please let Chris know. For a teaser video of the intended capabilities, see this video: (https://www.youtube.com/watch?v=fNylb42FPIc&list=UUc6HWbF4UtdKdjbZ2tvwiCQ)
LADYBUG
Monthly Bar Chart - After much demand from multiple parties, a new component to create monthly bar and line charts has been added. The component is particularly useful for plotting the outputs of the “Average Data” component like monthly EPW data or averaged monthly-per hour data. It also supports daily data and any type of Energy simulation results.
Wind Profile - To go along with the new capabilities of natural ventilation in Honeybee, Ladybug now has a fully fleshed-out Wind Profile component that allows you to visualize how wind speed changes with height in relation to your building geometry. The component is geared to understanding the conditions of prevailing wind and will be useful in the future for setting up CFD models. Credit goes to Djordje Spasic for adding in all of the new capabilities. In a similar vein, the appearance of the wind rose has also been improved thanks to suggestions from Alejandra Menchaca.
Faster Solar Adjusted Temperature - Thanks to the SolarCal method from the Center for the Built Environment at UC Berkeley (http://escholarship.org/uc/item/89m1h2dg), the solar adjusted temperature component now includes an option for a much faster calculation that produces results that are very close to those originally obtained with the genCumSky component. Instead of using the cumulative sky, the component can now accept the direct and diffuse radiation from the ImportEPW component. Over a whole year, this essentially takes a calculation that used to be a half-hour and shrinks it down to 10 seconds. Thanks again to those at UC Berkeley for keeping their work open source!
Instructions - Last but not the least, [It took me almost two years to understand this but finally] we have a text file that describes the installation step by step and is way easier to modify than a video. You can find it in the zip file. Credit goes to Chris!
We also want to welcome Anton, Patrick and Sandeep to the team. Anton has kicked off his development by working on a component to import and visualize epw ground temperature data and he will be continuing to develop components to bring in reliable precipitation data to Ladybug. With this basis, he will continue to implement Honeybee components for ground heat storage, earth tubes, rain collection and hot water systems. Patrick and Sandeep are working on integration of Honeybee to Energy Performance Calculator.
As always let us know your comments and suggestions.
Enjoy!…
rring to the above image)
Area
effective
effective
Second
Elastic
Elastic
Plastic
Radius
Second
Elastic
Plastic
Radius
of
Vy shear
Vz shear
Moment
Modulus
Modulus
Modulus
of
Moment
Modulus
Modulus
of
Section
Area
Area
of Area
upper
lower
Gyration
of Area
Gyration
(strong axis)
(strong axis)
(strong axis)
(strong axis)
(strong axis)
(weak axis)
(weak axis)
(weak axis)
(weak axis)
A
Ay
Az
Iy
Wy
Wy
Wply
i_y
Iz
Wz
Wplz
i_z
cm2
cm2
cm2
cm4
cm3
cm3
cm3
cm
cm4
cm3
cm3
cm
I have a very similar table which I could import to the Karamba table. But I have i_v or i_u values as well as radius of inertia for instance.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
dimensjon
Masse
Areal
akse
Ix
Wpx
ix
akse
Iy
Wpy
iy
akse
Iv
Wpv
iv
Width
Thickness
Radius R
[kg/m]
[mm2]
[mm4]
[mm3]
[mm]
[mm4]
[mm3]
[mm]
[mm4]
[mm3]
[mm]
[mm]
[mm]
[mm]
L 20x3
0.89
113
x-x
4,000
290
5.9
y-y
4,000
290
5.9
v-v
1,700
200
3.9
20
3
4
L 20x4
1.15
146
x-x
5,000
360
5.8
y-y
5,000
360
5.8
v-v
2,200
240
3.8
20
4
4
L 25x3
1.12
143
x-x
8,200
460
7.6
y-y
8,200
460
7.6
v-v
3,400
330
4.9
25
3
4
L 25x4
1.46
186
x-x
10,300
590
7.4
y-y
10,300
590
7.4
v-v
4,300
400
4.8
25
4
4
L 30x3
1.37
175
x-x
14,600
680
9.1
y-y
14,600
680
9.1
v-v
6,100
510
5.9
30
3
5
L 30x4
1.79
228
x-x
18,400
870
9.0
y-y
18,400
870
9.0
v-v
7,700
620
5.8
30
4
5
L 36x3
1.66
211
x-x
25,800
990
11.1
y-y
25,800
990
11.1
v-v
10,700
760
7.1
36
3
5
L 36x4
2.16
276
x-x
32,900
1,280
10.9
y-y
32,900
1,280
10.9
v-v
13,700
930
7.0
36
4
5
L 36x5
2.65
338
x-x
39,500
1,560
10.8
y-y
39,500
1,560
10.8
v-v
16,500
1,090
7.0
36
5
5
I have diagonals (bracings) which can buckle in these "non-regular" directions too, and they do. If I could add those values then in the Karamba model I could assign specific buckling scenarios..... I can see another challenge which will be at the ModifyElement component, I will not be able to choose these buckling lengths, in these directions.
Do you think this functionality can be added within short, or should I try to find another way to model these members?
Br, Balazs
…
lowing error:
Has anyone encountered this error before or know what I might have done incorrectly?
The error is thrown 6 times (once for every input and output param registered?), and then Grasshopper works normally. The plugin is shown as available in the toolbox, but can't be used without throwing the above error.
Any ideas on how to fix it?
At the moment my code is the following:
using System; using System.Drawing; using Grasshopper.Kernel; using Rhino.Geometry; namespace GridShellGrasshopperPlugin { public class GridShellComponent : GH_Component { public GridShellComponent() : base("Grid Shell", "gridShell", "Applies a grid shell to a surface", "Surface", "Util"){} protected override void SolveInstance(IGH_DataAccess DA) { Surface refSurf = default(Surface); if(!DA.GetData(0, ref refSurf)) return; Point3d start = default(Point3d); if(!DA.GetData(1, ref start)) return; Point3d end = default(Point3d); if(!DA.GetData(2, ref end)) return; DA.SetData(0, null); DA.SetData(1, 33.0); DA.SetData(2, null); } protected override void RegisterOutputParams(GH_OutputParamManager pManager) { pManager.Register_LineParam("Curve On Surface", "GeoCurve", "Curve on surface between two points"); pManager.Register_DoubleParam("Line length", "length", "Length of line on surface"); pManager.Register_GenericParam("Intersection points", "points", "Points of intersection"); } protected override void RegisterInputParams(GH_InputParamManager pManager) { pManager.Register_SurfaceParam("Reference Surface", "refSurf", "Reference surface on which to form the grid shell", GH_ParamAccess.item); pManager.Register_PointParam("Start point", "startPoint", "Start point of the first line"); pManager.Register_PointParam("End point", "endPoint", "End point of the line"); } public override void CreateAttributes() { } public override Guid ComponentGuid { get { return new Guid("11111111-1111-1111-1111-111111111111"); } } protected override Bitmap Icon { get { return base.Icon; } } } }
I'm using Rhino 4.0 SR9, dated 9th March 2011, and Grasshopper 0.8.0013, dated 5th July 2011.…
n common tasks like updating GH definitions, viewing images on the GH canvass, and augmenting existing study-types. Most of the improvements to Honeybee have been in the making for a while and are just getting into the spotlight with this release. Notably, a number of improvements have been made to support large-scale full building energy models, including fixes to memory issues with large models, better components for splitting building masses into zones, and the ability to store HBZones in external files. Additionally, the THERM workflows have gotten a boost and these simulations can now be run directly from the Grasshopper canvass.
As always you can download the new release from Food4Rhino. Make sure to remove the older version of Ladybug and Honeybee before you do so and update your scripts. So, without further adieu, here is the list of the new capabilities added with this release:
LADYBUG
Better Method for Updating Old Grasshopper Files - As many of you have come to realize, Ladybug + Honeybee is updated on a fairly regular basis, with a stable release roughly every 6 months and a github version that never ceases to improve itself on a weekly basis. For this reason, we realize that updating old Grasshopper definitions to use recent components is a challenge for many of us. While we’ve had some methods for this in the past, there were always hiccups, particularly when it came to components that had new inputs/outputs since the previous version. Accordingly, Mostapha has added a new “Ladybug_Update File” component that will automatically update any Grasshopper Definition to be synchronized with the version of Ladybug+Honeybee that is currently in your toolbar (aka. the components in your userobjects folder). If there is a component that has new inputs/outputs since the time you built the definition, it will be automatically circled in red in your GH definition and a newer version of the component will be automatically added right next to this component:
While you still have to do some manual connecting of inputs to the newer component in this case, it should be much faster than our older methods and will hopefully help your old definitions survive long into the future!
EPWmap Now includes OneBuilding Files - Mostapha has added a number of new features to the EPWmap web interface that the “Download Ladybug” component connects to. Among the improvements are a color wheel that quickly shows you how hot, cold, and comfortable a given climate is and, perhaps more importantly, there is now support for EPW files sourced from OneBuilding. With the addition of many more weather files, you should now be able to use Ladybug with ease for more locations across the planet. We should also note that the “Open EPW and STAT” component that downloads/unzips files from a URL now supports OneBuilding URLs.
New Image Viewer Component - Mingbo Peng has graced Ladybug with a fantastic new “Image Viewer” component that takes a given image file on one’s machine and displays it on the Grasshopper canvas. It also enables one to pull color data off of the image with ease by simply clicking on the pixel of the image one is interested in. This new component is useful for a wide variety of cases, including the viewing of screenshots after they have been taken with the “Ladybug_Capture View” or “Ladybug_Render View” components. However, many of you will likely recognize it as most immediately useful in workflows involving image-based Honeybee Daylight (Radiance) simulations. This is particularly true as Migbo has built-in the capability to read many image file types, including PNG, JPEG, GIF, TIFF and the High Dynamic Range (.HDR) image files that Radiance Outputs:
The following video gives a quick overview of the Image Viewer’s capabilities:
The new component can be found under the Ladybug_Extra tab and I think I speak for us all in saying thank you Mingbo for this great component!
New Sun Shades Calculator Released Under WIP - After over a year of software development and nearly a career's worth of geometric math development, a joint effort between Abraham Yezioro and Antonello Di Nunzio has produced a new sun shade design component that can be described as nothing short of “magical.” Based on a similar principle to the current “Ladybug_Shading Designer,” the new component takes an input of sun vectors and produces shade geometries that can block the vectors. However, in comparison to the shading designer, the range of shade options that are available in this new component is truly staggering, ranging from classic overhangs, louvers and fins to pergolas and custom shade surfaces. Perhaps more importantly, the calculation methods used by this new component are faster and more reliable. It can currently can be found under the WIP section of Ladybug and it will continue to evolve in new versions of Ladybug.
Renewable Component Now Support Sandia and CEC Photovoltaics Modules - Polishing off his many contributions to the “Renewables” section of Ladybug, Djordje Spasic has added support for a couple more ways of defining Photovoltaic modules for renewables estimation. Specifically, the Ladybug WIP section now includes components to import modules defined with the California Energy Commission (CEC) and Sandia Labs.
HONEYBEE
Support for OpenStudio 2.x - A few months ago, the National Renewable Energy Lab (NREL) released a stable version of OpenStudio version 2, which included a number of improvements in stability and available features. This stable release of Honeybee is built to work with the new version of OpenStudio and, in the coming months, Honeybee will be adding a few more capabilities to its OpenStudio workflows to support v2.x’s new capabilities. Most notable among these will be support for OpenStudio measures. Measures are short scripts written in Ruby using OpenStudio’s SDK to quickly edit and change OpenStudio models. They are fundamental to visions of OpenStudio as a flexible energy modeling interface and to Honeybee’s goals of being a collaborative interface between the architectural and engineering industries. Stay tuned for the next release for many of these new capabilities!
Critical Memory Issue Fixed for Large Energy Models - A number of you wonderful members of our community have been aware of computer memory issues with large Honeybee models for some time (examples: 1, 2, 3, 4). Namely, a model that is larger than 50 zones could quickly eat up 16 GBs of memory and change Honeybee from a fast-flying insect to something more reminiscent of a snail. We are happy to say that, after a much longer time than it should have taken us, we finally identified and fixed the issue. In this version of Honeybee, such large models can now be created using less than 2% of the memory and time previously. Thanks to all of you who made us aware of this and hopefully you will now reap the rewards of your struggle.
Split Building Mass Component Getting a Makeover - Many of you veteran Ladybug users will recognize Saeran Vasathakumar as one of the original contributors of Ladybug who added components for solar fans and envelopes years ago. Now he’s back with new components to split a building mass into zones that are truly revolutionary in their speed and methodology. Saeran has divided the new capabilities into two components (one for floor-by-floor subdivision and another for core-perimeter subdivision) and they both can be found under the WIP section of this release. In this WIP version, core-perimeter thermal zones can only be generated for all convex and very simple concave geometries. Most concave geometries and geometries with holes (or courtyards) in them will fail. However it can handle even very complex convex geometries with speed and ease. You can expect the component to start accommodating concave/courtyard geometries very soon.
Load / Dump HB Objects to File - Keeping in line with the support of large, full building energy models, this release includes full support for two components that can dump and load any HBObjects to a standalone file. All information about HBzones can go into this file including custom constructions, schedules, loads, natural ventilation, shading devices, etc. You can then send the resulting .HB file to someone else and they can load up the same exact zones in another definition. This also makes it possible to have one Grasshopper file for generating the zones and running the simulation and another GH definition to import results and color zones/surfaces with those results, make energy balance graphics, etc.
Write ViewFactorInfo to File - After many of you asked for it, the _viewFactorInfo that is output from the “Honeybee_View Factor” component can now be written out to an external file using the same Load / Dump HB Objects components cited above. For those of you who have worked with the comfort map workflows, you probably already know that calculating these view factors is one of the most time consuming portions of building a microclimate map. Having to re-run this calculation each time you want to open up the Grasshopper script is a nuisance and, thanks to this new capability, you should only have to run it once and then store your results in an external .HB file.
Transform Honeybee Components Modified for Large Model Creation - Many large buildings today are made up of copies of the same rooms repeated over and over again across multiple floors, or along a street, etc. Accordingly, one can imagine that the fastest way to create a full building energy model of such buildings is to simply move and copy the same zones several times. This is what a new set of edits to the Honeybee Transform components is aimed at supporting by allowing one to build a custom set of zones, translate them several times with a Honeybee_Transform component, then solve adjacencies on all zones to make a complete energy model.
Central Plants Available on HVAC Systems - While Honeybee has historically supported the assigning of separate HVAC systems to different groups of zones, each HVAC was always an entirely new system from the ground up. So a building with separate VAV systems for each floor would be modeled with a different chiller and boiler for each floor. While this can be the case sometimes, it is more common to have only one chiller and boiler per building but separate air systems for each floor. The new ‘centralPlant_’ options on the Honeybee coolingDetails and heatingDetails enable you to create this HVAC structure by making a single boiler and chiller for any HVAC systems that have this option toggled on. Furthermore, in the case of VRF systems, you can also centralize the ventilation system, using the grouping of zones around a given HVAC to assign which zone terminals are connected to a given heat pump.
More HVAC Templates Added - As the profession continues to push the industry standard towards lower-energy HVAC systems, Honeybee intends to keep up. In this release, we have included a few more templates for modeling advanced HVAC systems including Radiant Ceilings, Radiant Heated Floors + VAV Cooling, and Two Ground Source Heat Pump (GSHP) systems. Variable Refrigerant Flow (VRF) systems have also gotten a large boost as it is now possible to model these systems with more efficient water-source loops. The next release will include the ability to model central ground source systems that use hydronics for heating cooling delivery.
Run THERM Simulations Directly from Grasshopper - Anyone who has used the THERM workflow in the past likely realized that, while Honeybee can write the THERM file, you would still have to open model in THERM yourself and hit “simulate” to get results. Now that LBNL has started a transition to becoming more open, they have graciously allowed free access for everyone to run THERM from a command line. What this means for Honeybee is that you no longer need to open THERM at all in order to get results and you can now work entirely in Rhino/Grasshopper. This also opens up the possibility of long parametric runs with THERM models since you can now automatically run simulations and collect results as you animate sliders, use galapagos, etc. A special thanks is due to the LBNL team for exposing this feature, including Setphen Selkowitz, Christian Kohler, Charlie Curcija, Eleanor Lee, and Robin Mitchell.
All Options Exposed for THERM Boundary Conditions - To finish off the full implementation of THERM in Honeybee, a final component has been added called “Honeybee_Custom Radiant Environment.” This component completes the access to all boundary condition options that THERM offers, including separate radiant and air temperatures, different view factor models, and the specification of additional heat flux (which is typically used to account for solar radiation).
Improvements to Schedule-Generating Components - Many of you who have watched the Honeybee energy modeling video tutorials have likely gotten in the habit of using CSV schedules for everything. While this is definitely one valid way to work, it is not always the most efficient since simple schedules can be specified much more cleanly to EnergyPlus/OpenStudio and the use of CSVs can also make it difficult to share your energy models (since you have to send CSV files along with the schedules themselves). This release adds two new schedule components that should take care of a lot of cases where CSV schedules were unnecessary. The new “Constant Schedule” component allow you to quickly make a schedule that is set at a single value or a set of constantly repeating 24-hour values. The second component allows you to create “Seasonal Schedules” by connecting “week schedules” from the other schedule components along with analysis periods in which these seek schedules operate. Together, these will hopefully make our schedule-generating habit a bit better as a community.
Lastly, many of you may know Mingbo Peng as the current maintainer of the Design Explorer web interface and the Colibri components under TTToolbox. Both of these tools have been revolutionary in enabling “brute force” studies of design spaces (aka. Grasshopper scripts where one runs all combinations of a set of sliders). Now, Mingbo has graced Ladybug with the aforementioned image viewer component and it is with pride that we welcome Mingbo Peng to the development team!
As always let us know your comments and suggestions.Cheers!
The Ladybug Tools Development Team
…
GH, same as using sweep2 command in Rhino.
The one on the right is what I got so far (the output smooth our the kink of the original rails). Basically I am just following the methods provided by sdk sample: http://wiki.mcneel.com/developer/sdksamples/sweep2 .
The following is the function I copy and use directly from the SDK sample. By using this function, I can generate the sweep surface at right. But I want to have is the one in the middle with the kink edges. Can anyone show me how and where to modify he settings? I guess some sweep arguments need to be changed? I have try couples, such m_simplify, m_bSimpleSweep, m_bSameHeight, m_rebuild_count... but still cannot find a right combination for this function to output the sweep surface I want. Any suggestions or helps are very appreciated. Thanks for your help and time on this.
'Sweep2 function'----------------
Sub Sweep2( ByVal Rail1 As IOnCurve, _
ByVal Rail2 As IOnCurve, _
ByVal sCurves As List(Of IOnCurve), _
ByRef Sweep2_Breps As List(Of OnBrep))
'Define a new class that contains sweep2 arguments
Dim args As New MArgsRhinoSweep2
'Set the 2 rails
Dim Edge1 As New MRhinoPolyEdge
Dim Edge2 As New MRhinoPolyEdge
Edge1.Append(Rail1.DuplicateCurve())
Edge2.Append(Rail2.DuplicateCurve())
'Add rails to sweep arguments
args.m_rail_curves(0) = Edge1
args.m_rail_curves(1) = Edge2
args.m_bClosed = False
Dim section_curves As New List(Of OnCurve)
'Loop through sections to set parameters
For Each Section As IOnCurve In sCurves
Dim sCurve As OnCurve = Section.DuplicateCurve()
section_curves.Add(sCurve)
Dim t0 As Double = 0
If Not Edge1.GetClosestPoint(sCurve.PointAtStart(), t0) Then
If Not Edge1.GetClosestPoint(sCurve.PointAtEnd(), t0) Then
Dim s As Double = 0
sCurve.GetNormalizedArcLengthPoint(0.5, s)
Edge1.GetClosestPoint(sCurve.PointAt(s), t0)
End If
End If
args.m_rail_params(0).Append(t0)
Dim t1 As Double = 0
If Not Edge2.GetClosestPoint(sCurve.PointAtStart(), t1) Then
If Not Edge2.GetClosestPoint(sCurve.PointAtEnd(), t1) Then
Dim s As Double = 0
sCurve.GetNormalizedArcLengthPoint(0.5, s)
Edge2.GetClosestPoint(sCurve.PointAt(s), t1)
End If
End If
args.m_rail_params(1).Append(t1)
Next
'Set shapes
args.m_shape_curves = section_curves.ToArray
'Set the rest of parameters
args.m_simplify = 0
args.m_bSimpleSweep = False
args.m_bSameHeight = False
args.m_rebuild_count = -1 'Sample point count for rebuilding shapes
args.m_refit_tolerance = RMA.Rhino.RhUtil.RhinoApp.ActiveDoc.AbsoluteTolerance()
args.m_sweep_tolerance = RMA.Rhino.RhUtil.RhinoApp.ActiveDoc.AbsoluteTolerance()
args.m_angle_tolerance = RMA.Rhino.RhUtil.RhinoApp.ActiveDoc.AngleToleranceRadians()
Dim sBreps() As OnBrep = Nothing
If (RhUtil.RhinoSweep2(args, sBreps)) Then
For Each b As OnBrep In sBreps
Sweep2_Breps.Add(b)
Next
End If
Return
End Sub
…
r." I'm sorry to hear that, I take the interface and ease-of-use rather seriously so this sounds like a fundamental failure on my part. On the other hand, Grasshopper isn't supposed to be on a par with most other 3D programs. It is emphatically not meant for manual/direct modelling. If you would normally tackle a problem by drawing geometry by hand, Grasshopper is not (and should never be advertised as) a good alternative."What in other programs is a dialog box, is 8 or 10 components strung together in grasshopper. The wisdom for this I often hear among the grasshopper community is that this allows for parametric design."Grasshopper ships with about 1000 components (rounded to the nearest power of ten). I'm adding more all the time, either because new functionality has been exposed in the Rhino SDK or because a certain component makes a lot of sense to a lot of people. Adding pre-canned components that do the same as '8 or 10 components strung together' for the heck of it will balloon the total number of components everyone has to deal with. If you find yourself using the same 8 to 10 components together all the time, then please mention it on this forum. A lot of the currently existing components have been added because someone asked for it."[...] has a far cleaner and more intuitive interface. So does SolidWorks, Inventor, CATIA, NX, and a bunch of others."Again, GH was not designed to be an alternative to these sort of modellers. I don't like referring to GH as 'parameteric' as that term has been co-opted by relational modellers. I prefer to use 'algorithmic' instead. The idea behind parameteric seems to be that one models by hand, but every click exists within a context, and when the context changes the software figures out where to move the click to. The idea behind algorithmic is that you don't model by hand.This is not to say there is no value in the parametric approach. Obviously it is a winning strategy and many people love to use it. We have considered adding some features to GH that would make manual modelling less of a chore and we would still very much like to do so. However this is such a large chunk of work that we have to be very careful about investing the time. Before I start down this road I want to make sure that the choice I'm making is not 'lame-ass algorithmic modeller with some lame-ass parametrics tacked on' vs. 'kick-ass algorithmic modeller with no parametrics tacked on'.
Visual Programming.I'm not exactly sure I understand your grievance here, but I suspect I agree. The visual part is front and centre at the moment and it should remain there. However we need to improve upon it and at the same time give programmers more tools to achieve what they want.
Context sensitivity."There is no reason a program in 2014 should allow me to make decisions that will not work. For example, if a component input is in all cases incompatible with another component's output, I shouldn't be able to connect them."Unfortunately it's not as simple as that. Whether or not a conversion between two data types makes sense is often dependent on the actual values. If you plug a list of curves into a Line component, none of them may be convertible. Should I therefore not allow this connection to be made? What if there is a single curve that could be converted to a line? What if you want to make the connection now, but only later plan to add some convertible curves to the data? What you made the connection back when it was valid, but now it's no longer valid, wouldn't it be weird if there was a connection you couldn't make again?I've started work on GH2 and one of the first things I'm writing now is the new data-conversion logic. The goal this time around is to not just try and convert type A into type B, but include information about what sort of conversion was needed (straightforward, exotic, far-fetched. etc.) and information regarding why that type was assigned.You are right that under some conditions, we can be sure that a conversion will always fail. For example connecting a Boolean output with a Curve input. But even there my preferred solution is to tell people why that doesn't make sense rather than not allowing it in the first place.
Sliders."I think they should be optional."They are optional."The “N” should turn into the number if set."What if you assign more than one integer? I think I'd rather see a component with inputs 'N', 'P' and 'X' rather than '5', '8' and '35.7', but I concede that is a personal preference."But if I plug it into something that'll only accept a 1, a 2, or a 3, that slider should self set accordingly."Agreed.
Components."Give components a little “+” or a drawer on the bottom or something that by clicking, opens the component into something akin to a dialog box. This should give access to all of the variables in the component. I shouldn't have to r-click on each thing on a component to do all of the settings."I was thinking of just zooming in on a component would eventually provide easier ways to access settings and data."Could some of these items disappear if they are contextually inappropriate or gray out if they're unlikely?"It's almost impossible for me to know whether these things are 'unlikely' in any given situation. There are probably some cases where a suggestion along the lines of "Hey, this component is about to run 40,524 times. It seems like it would make sense to Graft the 'P' input." would be useful.
Integration."Why isn't it just live geometry?"This is an unfortunate side-effect of the way the Rhino SDK was designed. Pumping all my geometry through the Rhino document would severely impact performance and memory usage. It also complicates the matter to an almost impossible degree as any command and plugin running in Rhino now has access to 'my' geometry."Maybe add more Rhino functionality to GH. GH has no 3D offset."That's the plan moving forward. A lot of algorithms in Rhino (Make2D, FilletEdge, Shelling, BlendSrf, the list goes on) are not available as part of the public SDK. The Rhino development team is going to try and rectify this for Rhino6 and beyond. As soon as these functions become available I'll start adding them to GH (provided they make sense of course).On the whole I agree that integration needs a lot of work, and it's work that has to happen on both sides of the isle.
Documentation.Absolutely. Development for GH1 has slowed because I'm now working on GH2. We decided that GH1 is 'feature complete', basically to avoid feature creep. GH2 is a ground-up rewrite so it will take a long time until something is ready for testing. During this time, minor additions and of course bug fixes will be available for GH1, but on a much lower frequency.Documentation is woefully inadequate at present. The primer is being updated (and the new version looks great), but for GH2 we're planning a completely new help system. People have been hired to provide the content. With a bit of luck and a lot of work this will be one of the main selling points of GH2.
2D-ness."I know you'll disagree completely, but I'm sticking to this. How else could an omission like offsetsurf happen?"I don't fully disagree. A lot of geometry is either flat or happens inside surfaces. The reason there's no shelling (I'm assuming that's what you meant, there are two Offset Surface components in GH) is because (a) it's a very new feature in Rhino and doesn't work too well yet and (b) as a result of that isn't available to plugins.
Organisation.Agreed. We need to come up with better ways to organise, document, version, share and simplify GH files. GH1 UI is ok for small projects (<100 components) but can't handle more complexity.
Don't get me wrong, I appreciate the feedback, I really do, but I want to be honest and open about my own plans and where they might conflict with your wishes. Grasshopper is being used far beyond the boundaries of what we expected and it's clear that there are major shortcomings that must be addressed before too long. We didn't get it right with the first version, I don't expect we'll get it completely right with the second version but if we can improve upon the -say- five biggest drawbacks (performance, documentation, organisation, plugin management and no mac version) I'll be a happy puppy.
--
David Rutten
david@mcneel.com…
t does not run inside the Grasshopper thread).
A way for components to subscribe to a "New solution at the earliest conveinience the next time a solution is finished". This may include a small pause for grasshopper to redraw the canvas; or a pause to prevent locked-up scenarios and unescapable stuff.
Multiple components should be able to subscribe to this, and they should be expired at the same time. (Right now I'm using solution #2: When having a lot of input this causes a racing condition, where one of the two components will be expired, causing a "turn based scenario".
A no-queue solution: Multiple calls during a solution should be collected into one batch of components / params that should be expired.
This is the code I've tried
1: Adding a new handler at the end of a solution
GH_Document.SolutionEndEventHandler handle = null; handle = delegate (Object sender, GH_SolutionEventArgs e) { // first get rid of our handler again GrasshopperDocument.SolutionEnd -= handle; if (GH_Document.IsEscapeKeyDown()) return; try { // ExpireSolution(true); } catch (Exception ex) { RhinoApp.WriteLine("Exception in SolutionEnd event: {0}", ex.ToString()); } };
2: The Ghowl UDP way:
if (_doc.SolutionState != GH_ProcessStep.Process && _udpClient != null && !_askingNewSolution) { GH_InstanceServer.DocumentEditor.BeginInvoke((Action)delegate() { if (_doc.SolutionState != GH_ProcessStep.Process) { _askingNewSolution = true; this.ExpireSolution(true); _askingNewSolution = false; } }); }
My use cases are:
A USB Hid listener (Should be able to handle e.g. two gamepads at the same time) sending commands to a component. Events can arrive at high speeds; and should be able to know when it's save to actually request a new solution
A form that sends keystrokes or commands to (multiple) components on the canvas (one per device).
An embedded webserver
Looping (like: Hoopsnake, anemone, etc. Sending data back to one or more parameters on the canvas)
For most of these problems I've got a solution where one of these components is working. But most of the time combining them results into misery.
These are my questions:
What does ScheduleSolution() do? I've tried to use it - but it's behaviour seems erratic. Most of the expirations arrive quite laggy.
What is the difference between ExpireSolution(true) and ExpireSolution(false)? When is it safe to call either of them?
How do I determine if it's safe to request a new solution?
Any thoughts on a generic way to solve this (Rather than each component subscribing to events, a way to subscribe to an expiration at the next earliest conveinience?)
…