he default for Rhino, degree=5 gives you smoother curves, but each control point matters less, degree=11 is the highest degree Rhino allows. Apart from 2, degrees tend to be odd rather than even, though Rhino supports both.
In addition to the degree and the control points, Nurbs curves have knots. A single knot is just a number, and the list of all knots is called the knot-vector of a curve. The number of knots depends on both the degree and the control-point count, and the spacing of the knots affects the shape of the curve a little bit. If there are <degree> knots with the same value, then the curve is somewhat discontinuous at that location which could manifest itself as a kink or as a clamped end-point. However it is not possible by just looking at the shape of a curve to say where stacked knots might be, but you can use the Rhino _List command to inspect all details of a Nurbs curve.…
eroberfläche des Grasshopper Programms
Funktionsprinzip eines grafischen Algorithmus-Editors (Datenfluss)
Unterscheidung von Parametern (Datentypen) und Komponenten (Datenverarbeitung)
Erzeugung, Bearbeitung und Analyse von Geometrie-Typen: Punkte, Vektoren, Linien, Kurven, Flächen (surfaces, brep) und Netze (meshes)
Strukturierung der Daten anhand von Listen und Bäumen
unterschiedliche Verknüpfungsmöglichkeiten von Parametern (data matching)
praxisnahe Grundlagen der Geometrie und Vektorrechnung für generatives Design
effizienter Aufbau von parametrischen Modellen anhand Übungsaufgaben
Auszug von Daten aus Modellen für die Fertigung; Daten aus Tabellen (Excel, CSV) importieren, exportieren
Einsatz von benutzerdefinierten Komponenten (custom components)
Vorkenntnisse: Rhinoceros3d Benutzeroberfläche der Software: Englisch Unterrichtssprache: Deutsch
Details und Anmeldung:
www.vhs-sha.de
click: SUCHE
Kurstitel: GRASSHOPPER
oder direkt:
http://www.vhs-sha.de/index.php?id=90&kathaupt=11&knr=3151053&kursname=Grasshopper+I
Trainer: Peter Mehrtens
Kursdauer: 3 Tage / 8 Stunden pro Tag
Freitag, 19.07.2013, 08:00-17:00 Uhr Samstag, 20.07.2013, 08:00-17:00 Uhr Sonntag, 21.07.2013, 08:00-17:00 Uhr Ort: Volkshochschule Schwäbisch Hall, im Haus der Bildung
Teilnahmegebühr: 349,00 € Teilnehmerzahl: 4-10 Personen
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sando las nuevas tecnologías de la información en la arquitectura para la gestión del conocimiento de sistemas que desarrollen estructuras sustentables, desde los procesos de diseño generativos o algorítmicos. Donde se contempla la P.O.O. (programación orientada a objetos) como nuevo lenguaje de expresión para el arquitecto-diseñador en el siglo XXI.Los talleres están pensados para sigan un hilo conductual en el que al mismo tiempo que se enseña se investiga y experimenta. Por primera vez se contará con diversos miembros de SEED como docentes de forma presencial y por video conferencia, logrando de esta forma acercar a los especialistas que se encuentran en Europa a los asistentes de los talleres sin encarecer los costos.+info:http://www.studioseed.net/ adn-methodology/
Los talleres están dirigidos a personas que tengan o quieran conseguir un perfil alto de innovación, creatividad, flexibilidad: profesionales con actividades de dirección, gerencia, proyectistas, investigadores, así como a estudiantes a partir de 5to semestre en adelante. Cada taller abarca perfiles diversos de profesionales, mientras unos están más orientados a directivos y gerencias, otros más a proyectistas.
LOS TALLERES:FAB DIG I / ITESM – CEM / Estado de México / 20 hrs / 8 – 11 al de diciembre 2011 (En este taller no se aplican descuentos ni becas)PARAMETRIC GREEN HOUSING / Colegio de Arquitectos del estado de Jalisco (Por confirmar Sede) / Guadalajara / 20h + 5h proyecto / 30 enero 2012 al 4 de diciembre 2012FAB DIG II / ITESM – CEM / Estado de México / 30h + 5h proyecto / 8 a 12 febrero 2012TERCERA REVOLUCIÓN INDUSTRIAL: TIC`s + SOSTENIBILIDAD. Procesos y paradigmas emergentes / Querétaro / 20 hrs / 15 al 18 de febrero 2012INTRODUCCIÓN AL DISEÑO GENERATIVO / UAM-azc / DF / 8hrs / 13, 14 de enero (Costo representativo $650, máximo 40 personas, mínimo 15 personas)INTRODUCCIÓN A: SCRIPTING CON GRASSHOPPER ( Python) Y PLUGINS / Estudio SEED México / Estado de México / 30 hrs / 23, 24, 25 febrero y 1,2, 3 de marzo 2012…
Added by SEED studio at 3:30am on November 24, 2011
lane that looks like the outline of a gear wheel
2. Scale a bunch of copies of the curve to different sizes (I use 11 different sized curves.)
3. Move each curve vertically to a different Z-height
4. Rotate each curve to get the desired wavy/wiggly effect
5. Create a Loft surface using all the curves.
A critical step when creating the Loft is to add the curves in order - either top to bottom or bottom to top.
Step 4 can be omitted if you want a constant curvature throughout the final part. In this case all you have to do is Twist by the desired amount the Loft surface made from un-rotated curves. …
Added by Birk Binnard at 2:18pm on October 15, 2016
the total will be 44). when I looked into the order of splitting fragments it showed strange results, instead of having the splitting fragments ordered from 0,1,2,3,4,5...etc it starts with 0,10,1,2,3,.... and for the second group of fragments also a different order 10,1,2,3,4....
I don't know what causes such result because the
what can i do to rearrange it into the correct order 0,1,2,3,4,5,6,7,8,9,10..and make the new index starts from the edge of the original surface?
Question4.gh
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materials..(but a customized window material worked fine..). Does anyone have experience run into this error before? Please let me know!
"10. Runtime error (KeyNotFoundException): KeyError
11. Traceback: line 2145, in main, "<string>" line 2367, in script line 1097, in EPMaterialStr, "<string>" "
I'm also attaching my Rhino and GH file. Any help would be much appreciated.
Thanks!
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s the "Surface Populating" definition: I manage to populate my geometry over the surface, but after I bake it, I have to delete the boxes that define my components limits as well! Is there any way of populating and baking only the chosen component, without having to delete the boxes afterwards?
Secondly:
Basically: I am trying to cover a surface with two types of components [ an open one and a closed one] , which will be proliferated over my tubular surface according to the main sunlight direction.
1. I introduce the surface component.
2. I use "Divide Interval2" in order to have division into U and V.
3. i generate the target boxes [ "surfaceBox"] .
4. I use "Isotrim" ( same intervals) and "BRepArea" to find centroid of each area.
5. My "Curve" component introduces sun angle, with its "End Points".
6. I use "Vector 2Pt" to specify sun-light direction.
7. I want to measure the angle between sun-light and the surface normals, at the position of each component; after generating the centre points, I need the normals of each centre point to get the surface's points' UV, and "Evaluate" the srf at points.
8."Angle" and "Vector" components: I use them in order to evaluate the angle between the sun direction and the srf.
9. I convert this angle to degree by using a "Function" [ to see if the angle is bigger from the max.angle or not...]
10. Function "x,y" gives me boolean data.
11. Data become "Dispatch"ed...
12. Two "Morph" components , each one linked to one part of the "Dispatch" data, generate "closed" and "open" components over the srf.
The result should have been different types of components, based on the surface's curvature, diraction and sun-light direction...
I do not understand where the mistake is in this definition...
Thx in advance1
Spyros K.…
ells new products like the Firefly Interactive Prototyping Shield which mounts on top of your Arduino Uno and provides access to a number of useful input (ie. sensors) and output (ie. motors) devices. It includes features like:
Three linear slide potentiometers connected to analog pins 0, 1, and 2
Two-axis joystick connected to analog pins 3 and 4
Light sensor (photocell) connected to analog pin 5
Three push buttons connected to digital pins 2, 4, and 7
Red LED connected to digital pin 13
RGB LED connected to digital pins 3, 5, and 6
Two servo connections on digital pins 8 and 9
A connection to the Easy Stepper Driver (co-designed by Sparkfun Electronics and Brian Schmalz) to control stepper motors. The direction of the motor is controlled through digital pin 10 and the number of steps through digital pin 12
High-voltage MOSFET circuit capable of driving lights, valves, DC motors, solenoids, or anything else requiring higher voltage or current. The gate of the MOSFET is connected to digital pin 11 (PWM).
Some come take a look and let us know what you think!
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nch, xno items in one list)2 divide the list lenght value by the numer of items per branch needed3A generate a list with the series component: the step equal to the target numer of items per branch; the no of items equals the number of target branches
3B generate a list with the series component: the first number of the series equals to the number of items needed (-1 to account for the 0 index); the step size again equal to the target number of itmes per branch as 3A4 feed 3A & 3B to a domain component thus identifying the start -3A- and end -3B- of the domains by which the list will be subdivided5 use a subset component with the domains above thus creating 19 branches with lists having 5 items eachfor lists which are subdivided into branches when the target number of branches is not a multiple of the number of items contained in the list:6 identify if the target number of branches is a multiple of the list by using the modulus component fed by the list lenght -1- and the target number of branches7 identify last index in the 3B series with the item component (reversed to take the last value fed)8 add 6+7 above which dill define the start of the domain that will pick up the remanent items not accommodated in 59 add (+1) to 7 above to define the end of the domain that will pick up the the remanent items not accommodated in 510 feed 8 & 9 to a domain component11 include 10 as part of the subset in 5I'm now trying to understand the components mentioned by Michael...
sn
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be done easier, but later on the geometry will change and therefore this seems the better option. But coming back to the problem
First, there were some problems concerning the zone, although it seems solved still the “runenergysimulation” gives the following warning:
1. The simulation has not run correctly because of this severe error:
** Severe ** UpdateZoneSizing: Cooling supply air temperature (calculated) within 2C of zone temperature
Do one of you know what went wrong? It probably will solve most of it.
Second, “set Zone Thresholds” gives the following warning:
1. Solution exception:global name 'maxHumidity_' is not defined
However, the component is missing the max humidity input on the list, has this to do something with the error?
All the components are up to date.
I hope it will be an easy fix.
Gr Lars
“set Zone Thresholds” runtime error
{0;0;0}0. Runtime error (UnboundNameException): global name 'maxHumidity_' is not defined1. Traceback: line 80, in checkTheInputs, "<string>" line 282, in script
"runenergysimulation” report
{0;0}0. Current document units is in Meters1. Conversion to Meters will be applied = 1.0002. TypeError('Waarde kan niet null zijn.\r\nParameternaam: source',)3. Failed to copy the object. Returning the original objects...This can cause strange behaviour!4. [1 of 8] Writing simulation parameters...5. [2 of 8] No context surfaces...6. [3 of 8] Writing geometry...7. [4 of 8] Writing Electric Load Center - Generator specifications ...8. [5 of 8] Writing materials and constructions...9. [6 of 8] Writing schedules...10. [7 of 8] Writing loads and ideal air system...11. [8 of 8] Writing outputs...12. ...... idf file is successfully written to : c:\ladybug\unnamed\EnergyPlus\unnamed.idf13. 14. Analysis is running!...15. c:\ladybug\unnamed\EnergyPlus\eplusout.csv16. ......
Done! Read below for errors and warnings:
17. 18. Program Version,EnergyPlus, Version 8.3.0-6d97d074ea, YMD=2016.03.02 20:55,IDD_Version 8.3.019. 20. ** Warning ** IP: Note -- Some missing fields have been filled with defaults. See the audit output file for details.21. 22. ************* Beginning Zone Sizing Calculations23. 24. ** Warning ** GetInternalHeatGains: People="CLASSROOMOFFICEPEOPLE", Activity Level Schedule Name values25. 26. ** ~~~ ** fall outside typical range [70,1000] W/person for Thermal Comfort Reporting.27. 28. ** ~~~ ** Odd comfort values may result; Schedule="SCHOCCUPANCYSCHEDULE".29. 30. ** ~~~ ** Entered min/max range=[0.0,1.0] W/person.31. 32. ** Warning ** Calculated design heating load for zone=CLASSROOM is zero.33. 34. ** ~~~ ** Check Sizing:Zone and ZoneControl:Thermostat inputs.35. 36. ** Severe ** UpdateZoneSizing: Cooling supply air temperature (calculated) within 2C of zone temperature37. 38. ** ~~~ ** ...check zone thermostat set point and design supply air temperatures39. 40. ** ~~~ ** ...zone name = CLASSROOM41. 42. ** ~~~ ** ...design sensible cooling load = 25499.10 W43. 44. ** ~~~ ** ...thermostat set point temp = 0.000 C45. 46. ** ~~~ ** ...zone temperature = 15.334 C47. 48. ** ~~~ ** ...supply air temperature = 15.000 C49. 50. ** ~~~ ** ...temperature difference = -0.33433 C51. 52. ** ~~~ ** ...calculated volume flow rate = 197273.21341 m3/s53. 54. ** ~~~ ** ...calculated mass flow rate = 237634.19357 kg/s55. 56. ** Warning ** ManageSizing: For a plant sizing run, there must be at least 1 Sizing:Plant object input. SimulationControl Plant Sizing option ignored.57. 58. ************* Testing Individual Branch Integrity59. 60. ************* All Branches passed integrity testing61. 62. ************* Testing Individual Supply Air Path Integrity63. 64. ************* All Supply Air Paths passed integrity testing65. 66. ************* Testing Individual Return Air Path Integrity67. 68. ************* All Return Air Paths passed integrity testing69. 70. ************* No node connection errors were found.71. 72. ************* Beginning Simulation73. 74. ************* Simulation Error Summary *************75. 76. ** Warning ** The following Report Variables were requested but not generated77. 78. ** ~~~ ** because IDF did not contain these elements or misspelled variable name -- check .rdd file79. 80. ************* Key=*, VarName=ZONE PACKAGED TERMINAL HEAT PUMP TOTAL COOLING ENERGY, Frequency=Hourly81. 82. ************* Key=*, VarName=ZONE PACKAGED TERMINAL HEAT PUMP TOTAL HEATING ENERGY, Frequency=Hourly83. 84. ************* Key=*, VarName=CHILLER ELECTRIC ENERGY, Frequency=Hourly85. 86. ************* Key=*, VarName=BOILER HEATING ENERGY, Frequency=Hourly87. 88. ************* Key=*, VarName=FAN ELECTRIC ENERGY, Frequency=Hourly89. 90. ************* Key=*, VarName=ZONE VENTILATION FAN ELECTRIC ENERGY, Frequency=Hourly91. 92. ************* Key=*, VarName=EARTH TUBE FAN ELECTRIC ENERGY, Frequency=Hourly93. 94. ************* Key=*, VarName=PUMP ELECTRIC ENERGY, Frequency=Hourly95. 96. ************* Key=*, VarName=ZONE VENTILATION TOTAL HEAT LOSS ENERGY, Frequency=Hourly97. 98. ************* Key=*, VarName=ZONE VENTILATION TOTAL HEAT GAIN ENERGY, Frequency=Hourly99. 100. ************* Key=*, VarName=EARTH TUBE ZONE SENSIBLE COOLING ENERGY, Frequency=Hourly101. 102. ************* Key=*, VarName=EARTH TUBE ZONE SENSIBLE HEATING ENERGY, Frequency=Hourly103. 104. ************* EnergyPlus Warmup Error Summary. During Warmup: 0 Warning; 0 Severe Errors.105. 106. ************* EnergyPlus Sizing Error Summary. During Sizing: 3 Warning; 1 Severe Errors.107. 108. ************* EnergyPlus Completed Successfully-- 5 Warning; 1 Severe Errors; Elapsed Time=00hr 00min 4.65sec109.…