basis" problem ... all of a sudden - quite recently - a girl posted the MITESIGF (Most Important Thread Even Seen In Grasshopper Forums). She doesn't even realized that: she's novice:
http://www.grasshopper3d.com/forum/topics/array-1
4. Why this MITESIGF is MITESIGF? For 2 reasons:
4.a: Wooden pairs (Beams) Profile Curves (belonging in some tree) MUST allow individual control on a per "item basis" (OK, that's obvious) - see Images posted in the thread. No attractor (or any other "global" policy) can cut the mustard here (to tell you the truth this happens in 99% of pure engineering cases, but they appear very rarely in GH Forums - if at all, mind). If the profile curves are defined with 5 points (or 9 for the double thing) we need "on-the-fly" control over this Array (like the radii in your Sphere Manipulator) :
4.b: Critical Bottom-to-Top issues arise: Create a "global" topology (call it "parent") - the beams - and then place real-life "components" (call them "childs") that affect (most probably) the "parent". OK, that's impossible to do with GH/Rhino (peace of cake with CATIA/Microstation) but you can "approximate" things up to a point. Alternatively: you can "trigger" some interest from GH/Rhino developers if they have any AEC market(s) in mind.
Topic 4.a requires the master-to-slave slider thingy (iterate over branches (index slider:master) > reset the 5 values (value slider:slave) > modify them on the fly > save > increase/decrease branch > ...).
Other than that my definitions are far more challenging than this simple case ... but ... anyway ... long is the path (and hilly).
more soon.
best, The Troll
…
t the maximum potential with the bridge BIM+PARAMETRIC DESIGN ;D
During this Intense Week, we will learn about the power of Rhino + Grasshopper + ArchiCAD with Professional and Useful examples for our Normal Working day :D
You will get Advanced Library Files + Personal Web + Knowledge and Skills to start using this incredible Methodology ;D
Also, the week is having Lectures from different Experts sharing their Computational Working Experiences ;D And Jam Sessions! opening the door to 5 interesting topics to research, learn and experiment together :D
2020 is your YEAR ;D !!!
Complete details and registration……
nter the programming world and tinker more complex, interactive solutions. We will also explore advanced programming paradigms. There is no class official programming language, as both C# and Vb.Net are possible on the participant’s side, and all examples will be provided in both C# and Vb.Net. Additionally, we will see how to get started writing full .Net plug-ins. Finally, we will have time to explore user’s own proposals on the third day.
Day 1 Morning: programming introduction in .Net
• The Grasshopper scripting components. Choosing a .Net language. Language developments
• Variables declaration, assignment and utilization. Operators. Methods [functions]. Calls
• Classes: declaration and instancing. Constructors. Importing a namespace. On3dPoints, OnLines
• Arrays declaration and usage. Lists. Adding to arrays and lists, advantages and opportunities.
Afternoon: patterns
• About OOP (object oriented programming) as opposed to procedural programming. Discussion
• Example of OOP good code reuse: sorting points by coordinates using the .Net SDK classes
• Lists as input parameters. Trees as input parameters. Usage and limitations
• Finding resources: on the net with website that can help getting started and troubleshoot. And books
Day 2 Morning: extending Grasshopper functionality with our definitions
• Store data between updates. The use of fields [globals, or static locals]
• Examples on how to use stored data between updates: a simple agents simulation
• Baking geometry with scripting directly into the Rhino document. Baking with names
• Passing custom types from a scripted component to another one. Our own code reusability
• Rendering an animation from Grasshopper. How to get started and final results
Afternoon: customizing our tools
• Our Rhino plug-in with Visual Studio C# [Vb.Net] Express Edition & wizard. Parametric mesher
• Writing a custom Grasshopper component: hacking an exporter for our data to Excel
Day 3 All day: personal project
• Rehearsal on any example from the first two days. A project that you want to start on your own, being it a Rhinoceros plug-in, a Grasshopper assembly or a script. Example might be to send data through network with UDP to Processing
MINIMUM REQUIREMENTS
A good foundation of Grasshopper visual programming is mandatory. You will need a level which corresponds to the Grasshopper 101 course outline. Examples of things that will not be covered in this course are: sorting document spheres by diameter, paneling of a surface with grasshopper components. You are expected to already know these from the Grasshopper course.…
connected hyperspace where architecture can be fluid, flexible and vivid, yet the aspect of materiality requires more attention.
Action-designed structures begin to move beyond the utopian proposals of the 20th century’s manifestos and hold a place in the world of realized designs. The AA Athens Visiting School aims to bring users closer to the built environment while revisiting habits of designing, building and experiencing space through materiality. Understanding materiality and form as a ‘unified whole’, the programme integrates manufacturing techniques through the experimentation fabrication of prototypes at a 1:1 scale.
Prominent Features of the workshop/ skills developed
Participants become part of an active learning environment where the large tutor to student ratio allows for personalized tutorials and debates.
The toolset of the Athens VS includes but is not limited to Processing and Grasshopper for Rhinoceros, as well as design analysis software.
Participants gain hands-on experience on digital fabrication.
Design seminars and a series of lectures support the key objectives of the programme, disseminating fundamental computational techniques, relevant critical thinking, theoretical understanding and professional awareness.
Applications
1) You can make an application by completing the online application found under ‘Links and Downloads’ on the AA Visiting School page. If you are not able to make an online application, email visitingschool@aaschool.ac.uk for instructions to pay by bank transfer. 2) Once you complete the online application and make a full payment, you are registered to the programme. A CV or a portfolio is NOT required.
The deadline for applications is 28 June.
Location AKTO College – Athens Campus 11Α Evelpidon Street (Pedion Areos) Athens, 113 62, Greece
Fees
The AA Visiting School requires a fee of £695 per participant, which includes a £60 Visiting membership fee. Fees do not include flights or accommodation, but accommodation options can be advised.
Eligibility The workshop is open to current Undergrad and Graduate architecture and design students, PhD candidates and young professionals. Software Requirements: Adobe Creative Suite, Rhino 5.
For more information, please visit:
http://www.aaschool.ac.uk/STUDY/VISITING/athens
http://ai.aaschool.ac.uk/athens/
For inquiries, please contact:
alexandros.kallegias@aaschool.ac.uk…
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
…
you working on a PV system which will power a domestic hot water boiler?
To answer your questions:1) Each grasshopper component (ghpython being one of those too) is using grasshopper's data matching algorithm. This algorithm takes care of complex issues which may arise from combining lists with single items, data trees with different number of items per branch and so on.I think there is a way of introducing a call to other processor's threads per each inputted surface, but this will be a very difficult job, as it will require writing a custom data matching algorithm. I do not think I am up to that task.Instead I tried to introduce the multithread only to the final part of the PVsurface component and one of its time consuming parts: calculation of sun angles, solar radiation and ac/dc power output.I attached the test file below, but sadly it didn't go well: the multithreaded version mostly runs at the same time as the regular version.I do not think I am qualified enough to answer why is that so, but I think that it may have something to do with the type of the function that the multithreading is applied to: the code is suppose to run few separate functions a couple of thousand times, and work with a couple of lists. From my experience, the multithreading works the best when a single list or two are supplied to a single function. I may be wrong on this.I am very sorry to say that I can not implement this feature.2) I am not familiar if open source PV modules database has been released.But one can always download the data for specific modules from producers websites. It can then easily be transferred to a .csv file or other text file.Ladybug Photovoltaics are based on NREL's PVWatts model.In comparison with other commercial software applications, PVWatts offers a more generalized system model, with some of the values and characteristics being assumed or embedded.The Fuentes empirical thermal model we are currently using follows the same logic: it generalizes the Module characteristics. The following characteristics are only editable: module efficiency, temperature coefficient and module mount type.It may be possible to replace Fuentes with some other, less generalized 5 parameter thermal model. But as an architect, I would definitively need help on this.
Sorry if my reply did not fulfill your expectations, and thank you for the kind words!…
o Common - just like C#. But Rhino Python has a "Scripting Language Wrapper" which breaks commonly used taks down to simpler functions.
Here's a general Example:
Take a look at the code on this website http://wiki.mcneel.com/developer/rhinocommonsamples/addline). Generally it's Rhino Common code in three language to create a line. They look equally difficult.
But if you use Rhino Python Scripting you can use an simplified syntax to get the same result. It's very similar to Rhino Script.
The code would be:
import rhinoscriptsyntax as rsstart_point = rs.GetPoint("Get start point")end_point = rs.GetPoint("Get end point")line_id = rs.AddLine(start_point, end_point)
OK - No Error Tracking here, but still you can see that the syntax is much simpler. (And in the end you just have less lines of code you have to debug.
And the good thing about Rhino Python is, that you can mix these approaches. Once you reach a level where Rhino Python Script doesn't get you there, which by the way happens very rarely, you can still use the Rhino Common methods.
Also, in Python Sycripting 99% of what you probably would like to do is available as a "wrapped" script function.
Rhino Python Script is currently also better documented than Rhino Common for C# and VB.Net. If you have used Rhino VB Script before, these functions will be very familar to you.
I'm not sure, why it's currently a separate plug-in. I belive the reason is that Rhino 4 (which is supported by GH) doesn't support Rhino Python. Also it's currently WIP, so it needed to be updated more frequently than GH itself. In the long run (I believe) it might be integrated into GH as a general component
- Martin
P.S.: To use Rhino Python within GH is a little more tricky than my example - but nothing compared to developing C#
P.S.2 Here's the code with Error Tracking:
import rhinoscriptsyntax as rsdef AddLine(): start_point = rs.GetPoint("Get start point") if start_point is None: print "No start point was selected" return end_point = rs.GetPoint("Get end point") if end_point is None: print "No end point was selected" return line_id = rs.AddLine(start_point, end_point) return line_idAddLine()
…
rves/holes. However, the Kangaroo script itself is prone to locking up so it seems like it might take forever. You can even double click stop the timer from the Windows task bar, I hadn't noticed that before:
You have to use that or right click disable the timer since even with the Reset toggle button input set to True the timer itself locks up the script a bit when you are changing things around.
Just setting the min/max numbers both to a desired mesh size gives a uniform mesh:
Oh weird, it's about if the timer is right click set to so small an interval that it gets ahead of Kangaroo! When you see how long each cycle is taking with the Display > Canvas Widgets > Profiler you just set the timer for above that and the interface comes back into being responsive. It only takes a few Kangaroo cycles to do the inflation, so a full second timer interval is even workable.
A finer mesh:
It's funny running it so slow since it overinflates at first, bulging out, before it equilibrates.
You have control over inflation pressure and mesh stiffness, for a variety of effects.
This is a good system once I realized the timer needed to be mellowed out.
What made it work was the fast custom meshing since a normal mesh is awful and MeshMachine wouldn't work with sharp corner holes at all, breaking out of the boundary even if I fixed curves or vertices or did the equivalent with NURBS surfaces instead of a starting mesh.
There is an initiation time for Kangaroo that doesn't show up on its Profiler time that happens even with the timer off.
There are some fine areas that can't inflate with a reasonable mesh setting:
Worth playing with but no match for ArtCAM since it suffers odd delays in between working fast. If I could get better 2D meshes, that were more adaptive it would be better, but MeshMachine is one of the only re-meshers I know and it's broken for even mildly sharp hole features.
Ah, how about a crude mesh that is then subdivided, guaranteeing inner vertices everywhere? Sort of works, but is still too dense. Way too dense to even do anything. The subdivision triangulates the quads, vastly increasing the mesh wire density. Better just to make a finer initial mesh with plenty of quads.…
Added by Nik Willmore at 12:57am on February 21, 2016
size component supported only ground PV panels and angled roof PV panels.
Download the newest PV SWH system size component from here (Click on "View Raw" to download it. Then move the downloaded .ghuser file to File->Special Folders->User Objects Folder, an confirm to overwrite it with previously located one).
Just a few opinions on the project you are currently working on:This kind of fixed, non-transparent (overhang) PV panels attached to a building facade are vert convenient for locations with higher latitudes.The reason for this is because they (fixed overhang PV panels) are dimensioned according to the sun position at summer solstice. Elevation angles on summer solstice at higher latitude locations are lower, than those of lower latitude locations.Due to Incheon's low latitude (37), you will get rather short length of the PV panels* : less than 10 centimeters (0.097 meters in the attached .gh file below). As you have mentioned, Galapagos needs to be used too.I will just mention some of the good and bad ways in which the upper issue could be somewhat avoided:1) Increasing the vertical distance between PV panels (PV panels appear above every second window).2) Increase the tilt angle. This will increase the length of PV panels also, but will decrease the final annual AC energy output.An example of this solution has been applied at FKI building in Seoul (latitude: 37N):I already did some tests (with tilt angles: 40, 45, 55) and this does not seem like a good solution, though.3) Shrinking the "sun window" by using the minimalSpacingPeriod_ input. In Photovoltaics, a planner is suppose to make the 9h to 15h part of the sun window free of any obstructions. If you try to decrease the "sun window" to 10 to 14h, the length of your PV panels will increase. You can try to experiment a little bit with this (set your minimalSpacingPeriod_ to 21th of June 10 to 14hours). In general, shrinking the sun window on summer solstice is not a good principle during planning.4) Using tracking PV panels, not fixed ones. But Ladybug Photovoltaics components do not support this kind of PV systems. They only support fixed ones.I would personally go with the first option. You can also experiment with the second and third one.Comment back if you have any other questions.-----------------------* By "length of the PV panels" I mean the: tiltedArrayHeight_ input of the PV SWH system size component.…