Virtual Calit2 Building

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The goal the Virtual Calit2 Building is to provide an accurate and accessible virtual replica of the Calit2 building that can be used by any researcher or scientist to conduct projects or tests that require the need for a detailed architectural layout.

Contents

Proposed Projects Using the Virtual Calit2 Building

Michael Bajorek

In the news: Calit2 Collaborates with Architects and UC San Diego Neuroscientists to Study How 'Way-Finding' Affects the Brain

Contributors

Daniel Rohrlick continues making further additions to the existing model. The first floor of the Calit2 building is coming closer to completion.

Philip Weber provided excellent assistance with model loading techniques.

Vinh Huynh.

Mabel Zhang completed adding floors 3-6; completed the stairs; added the first set of interactive dynamic elements (automatic doors, working elevators, indoor light, 24-hour sunlight animation, sunlight according to system clock) to make the model more realistic; optimized the model (by adding MultiRes modifier in Max, shrinking the textures, adding the DEFs/USEs for ImageTextures, eliminating continuously generated polygons, recreating instances from copies, etc.); added the metaloader to selectively turn on/off building floors or layers; and divided the copy of the building into individual files for more object-oriented organization.

General Structure

As dynamic elements were added, a more object-oriented structure is needed to maintain the model files.

The entire model is saved as one Max file, then from an individual or multiple layers, smaller files are saved again for final export. Currently, the entire model is organized into these parts:

  • A loader to run the model and allows turning on and off layers to allow for maximum speed; manual VRML script.
  • Main model, this is the exterior of the building and miscellaneous parts; this inlines inlineDoorAnimated.wrl, inlineElevInit.wrl, and inlineLightSwitScript.wrl for corresponding dynamic effects.
  • Floor 1 in the main building and furnitures; exported directly from 3ds Max file's corresponding layers.
  • Floor 1 New Media Arts Wing rooms; exported directly from 3ds Max file's corresponding layers.
  • Floor 2; exported directly from 3ds Max file's corresponding layers.
  • Floor 3; exported directly from 3ds Max file's corresponding layers.
  • Floor 4; exported directly from 3ds Max file's corresponding layers.
  • Floor 5; exported directly from 3ds Max file's corresponding layers.
  • Floor 6; exported directly from 3ds Max file's corresponding layers.
  • All animated doors; this file contains only those doors that are animated; physical door objects are exported directly from 3ds Max, partial VRML code is added from modifying exported code.
  • Elevator initializer; initialize and create 3 elevators from a script PROTOtype (see below); mostly manual VRML script.
  • Elevator prototype; include code for 1 set of elevator's movement, audio, and other operations; the initializer creates 3 copies of this prototype to create 3 independent sets of elevators; physical objects are exported directly from Max with 1 line of code changed to link to the script, core logic is done by manual VRML script with JavaScript.
  • Light switch; include code for light object's on and off controlled by 2 separate switches; physical objects are Max-exported, logic is manual VRML script with JavaScript.
  • (Elevator physical objects; not directly required for run-time, but contains elevator objects exported from Max; the entire content of this file is pasted into the Elevator prototype file in order for the logic to link to objects.)
  • (Light switch physical objects; not directly required for run-time, but contains light objects exported from Max; the entire content of this file is pasted into the Light switch file in order for the logic to link to objects.)
  • (A readme file prepared for future maintenance; include most, if not all, of the necessary changes that need to be made to a directly Max-exported file for all the parts to run correctly.)

Modeling in Autodesk 3ds Max

Modeling in Max with VRML export in mind

Because the final version of the model is in VRML format, during the modeling process in 3ds Max, the most important thing to keep in mind is that not all effects will export to VRML. 3ds Max comes with a detailed user reference that includes some useful tips and exporting rules on VRML. Not all materials are exported, not all lights are exported, different geometry types export to files of significantly different sizes, etc.

Manual Work After Export

From many websites focusing on projects using 3ds Max + VRML, it is suggested that the Max-exported VRML file should be checked and edited manually for the final version. For a static model, this is quite simple; the most often hand operation would probably be commenting out automatically generated looping timers and interpolations, which will continuously generate polygons during run-time. However, for a model with logic scripts, the exported code must be combined with the manual script into a single file for the effect to work; simply inlining the exported object file or the script will not suffice, because VRML requires that the script and the objects be in the same file for the linking to take effect, otherwise syntax errors will result. This means that either the exported file contents will need to be pasted into the script file, or vise versa, so a clear structure and documentation is even more important. This is the reason that we placed the script and the objects in the same file, instead of separating them for easy maintenance.

For more manual modifications required, see relevant sections below.

Dynamic Elements

Automatic Doors

These are probably among the simplest dynamic elements to implement; nevertheless, they are a nice addition.

Key elements:

  • VRML97 Proximity Sensor (to detect user entrance to the area around the door)
  • VRML97 Time Sensor (to control animation of door's opening or closing)


The method is very straight forward. For each set of door(s), first we create the door's opening animation in Max by turning on AutoKey, scrolling to a frame (e.g. 30), rotating the door about its axis, then copying frame 0 to a later frame (e.g. 60). Now create a proximity sensor around the door(s), extending the sensor's length and width as far as desired. Then we created two time sensors, one for the door opening animation (frame 0-30), the other for the closing animation (frame 30-60). The time sensors' controlled frames can be set in 3ds Max Modify Panel. Finally, link the proximity sensor to the time sensor in 3ds Max (This appears as a ROUTEing in exported VRML code), and now the door(s) will open as the user enters the space enclosed by the proximity sensor.


To close the doors when the user leaves the space, although we have seen a few discussions online that suggest that it can be done within 3ds Max, we could not find a way in Max. Thus we accomplished the automatic door closing by manually editing the exported code. The code we need to change is at the very end of the exported wrl file. For a door with the above linking done, its corresponding code at the end of the wrl file looks similar to:

ROUTE sensor_prox_floor1aud3.enterTime TO sensor_time_floor1aud3_1-TIMER.startTime

where sensor_prox_floor1aud3 is a proximity sensor of a door named floor1aud3, sensor_time_floor1aud3_1-TIMER is the time sensor controlling this door's opening animation (indicated by the suffix _1). To make the door automatically close, copy the above line and replace 2 places so that the new additional line looks like:

ROUTE sensor_prox_floor1aud3.exitTime TO sensor_time_floor1aud3_0-TIMER.startTime

where the proximity sensor's enterTime is changed to exitTime, and the time sensor's name's suffix is changed from _1 to _0 because our naming strategy is _1 for the sensor controlling opening animation, _0 for the one controlling closing.

Keep both lines and do the same with the rest of the ROUTEing lines at the end of the exported file. (The other ROUTEing codes in the file are for the time sensors, door objects, etc., not related to the proximity sensor.)

Now the door will open when the user approaches it and close when the user leaves it.




....will have gif

Working Elevators

We used the German Mailand Mercedes car dealership model's elevator core code as a reference and built our own set of code to fit the Calit2 elevators.

The elevator has 2 parts, an intializer and a user-defined PROTOtype file. (PROTO is a keyword in VRML, stands for PROTOtype, and just means a user-defined data type.) The PROTO file defines one set of elevator, including its physical objects and all necessary scripts. The initializer creates 3 instances of this PROTOtype at the corresponding locations of the 3 main elevators in the building.

The length of the the core PROTO script, including the documentation, is more than 1000 lines, not including the exported objects, so it might be inconvenient to scroll through them here. However, detail documentation is included in the actual files.


A drawback of the current approach is that it cannot simulate the exact logic of the elevators in the real building. The virtual elevators currently operate independently, while the real ones are dependent. For example, in reality, there are 2 sets of buttons to call the elevator, and when a user calls the elevator from a floor, whichever elevator cab that is the most "convenient" will come to the user; in the virtual building, there are 3 sets of call buttons, and each elevator responds only to the set of buttons linked to it, meaning that the user controls whichever elevator will come by pressing on the corresponding set of buttons. We took the current approach because it involves less logic and linking and is less time-consuming; it only requires 1 set of definitions that can be initialized 3 times to generate 3 elevators. However, simulating the realistic logic will make the model more intelligent and believable.


Light Effects

VRML has three types of lights built in:

  • PointLight
  • DirectionalLight
  • Spotlight

Each one corresponds to these 3ds Max lights, respectively:

  • Omni
  • Free/Target Direct
  • Free/Target Spot

where the target lights can be used to help define the rotation of the light objects, but the automatically generated loop TRUE timer might need to be commented out. See the "Automatically Generated INTERPs and TIMERs" section below.

See the Lighthouse 3D description on lighting nodes for detailed information about VRML lights.


VRML does not support real shadows. To work around it, we can precalculate the texture maps and save them to the maps directory, then apply the textures to the objects in Max.

Because no shadows are calculated during run-time, don't be surprised if a light leaks all throughout the world. Adjust the attenuation by hand if needed so that the light leak is not as obvious. Sometimes turning on the headlight can help reduce the effect.


Like in Max, VRML browsers have a headlight on by default, if no lights are present in the scene. However, as soon as one light is added into the scene, the headlight is automatically turned off at startup. We can set the headlight to be on by manually editing the exported code:

Original code:

# This code is automatically exported from 3ds Max when a light is present in the scene
NavigationInfo { headlight FALSE }

Change to:

# To turn on headlight at world startup
NavigationInfo { headlight TRUE }


Indoor Lights

These are usually simulated using point lights (Omni in Max) because a spotlight only lights up a cone-shape area, and a directional light is located far far away from the world and therefore lights up everything in the direction it faces, which is usually not the desired result of an indoor light.

Point light fields taken from the above website, see here for detailed information about point lights:

PointLight {
  on TRUE
  intensity 1
  ambientIntensity 0
  color 1 1 1
  location 0 0 0
  attenuation 1 0 0
  radius 100
}

Attenuation:

Only "Far Attenuation" defined in 3ds Max is exported. "Near Attenuation" is not. Even so, Max does not export the correct far attenuation either; the values will need to be changed by hand after export. See "Misc. Debugging Ideas and Tricky Surprises" > "Light Attenuation" section below for manually adjusting the attenuation.

Radius:

The radius field does not seem to have an effect in OpenCOVER. We tried radii ranging from 5 to 500, and the effect always came out to be the same. Thus we only adjusted the attenuation field to generate lighting effect close to reality.


Sunlight

While the 3ds Max Daylight system, which includes a sunlight and a skylight object, seems perfect for the goal, it does not export to VRML with the light effects. Therefore to simulate sunlight, the options are directional or point lights.

We used a point light for the sun because it was much easier to animate than a directional light; although the animation process are the same for both in Max, they are different in VRML. VRML light objects are exported in a hierarchy with the root parent being a group name to hold the animation time sensor, position interpolator, rotation interpolator, and the actual light source (e.g. the DirectionalLight node). When an animation is created for a directional light, the animation time sensor routes to the root parent's position/rotation interpolater's key, which will set the corresponding keyValue, and this affects all its children's position. The problem is, VRML directional lights do not have a position/location field but instead, a direction field. Thus when the position of the root parent changes, although the light source's position also changes, the direction field does not. This results in no change in light direction. For the light direction to be changed, we need to manually route the time sensor to the direction field of the light source, not the position/rotation interpolator keyValue of the parent. So the routing would go from the time sensor's fraction_changed event to some 3-value vector, which then routes to the light source's direction field. The most convenient 3-value vector is the position interpolator's keyValue, which will need to be defined to be exactly the same as the values we want the direction field to have. It can be defined this way by moving the light object in max, or by writting the vector array manually. For our purpose, we needed the sun to rotate around the hemisphere, so the light direction will have both positive and negative values in its vector. This meant moving the sun object far, far away from our hemisphere which is not around the origin of the world, otherwise writing the coordinates manually. Therefore, we chose the point light approach, which does not require any manual effort to animate a 24-hour sun rotation around the hemisphere.


We implemented two features for the sunlight:

  • 24-hour sunlight animation at the press of a button (8 seconds animation)
  • Sunlight effect according to the current system clock


The 24-hour animation can be entirely done in Max. We used a circular spline to define the sun's path at 60 degrees to the grass plane, and set a path constraint on the omni sun object to follow the circular path in 240 frames, equivalent to 8 seconds in real time.


The system clock function requires some JavaScript to be inserted into the exported VRML file. It uses the JavaScript "date" object to create an instance of it, and uses the objects getHours() member function to obtain the system clock hour, and then move the omni sun object to its appropriate place in the sky. Other member functions can be used to obtain the weekday, date, minutes, etc., but we only used the hour for the sun's approximate position.

To move the sun to its appropriate position, we made a correspondance table for the hour, frame, and the key array in the exported sun object's position interpolator field. An if-statement or switch-statement can be used to check the current system hour returned by the date object instance, then assign the corresponding key value to an SFFloat type eventOut, which will be set to route to the sun's position interpolator to translate the sun to its position specified in the keyValue array. Each value in the key array automatically corresponds to the value with the same index in the keyValue array within the sun object's definition.

There are detailed information in the README file and the text files placed with the actual model, but here is the current correspondance table for the sun object mentioned above, it may change as the sun's animation frames are changed in Max:

For the following table,
hour = hour in the day;
frame = hour * 10 as set in Max when creating animation;
frmNw = multples of 3 closest to frame;
thkey = key array index + 1;
key = corresponding #th key in the key array in the exported omni sun object's "sun-POS-INTERP PositionInterpolator".

hour	frame	frmNw	thkey	key
0	0	0	1st	0
1	10	12	4th	0.0375
2	20	18	6	0.0625
3	30	30	10	0.1125
4	40	39	13	0.15
5	50	48	16	0.1875
6	60	60	20	0.2375
7	70	69	23	0.275
8	80	81	27	0.325
9	90	90	30	0.3625
10	100	99	33	0.4
11	110	111	37	0.45
12	120	120	40	0.4875
13	130	129	43	0.525
14	140	138	46	0.5625
15	150	150	50	0.6125
16	160	159	53	0.65
17	170	168	56	0.6875
18	180	180	60	0.7375
19	190	189	63	0.775
20	200	198	66	0.8125
21	210	210	70	0.8625
22	220	219	73	0.9
23	230	228	76	0.9375
(24	240	240	80)	0.9875

VRML Scripting + JavaScript in General

To use JavaScript in a VRML wrl file, create a script node, and use an inline url to include the javascript:

DEF WhateverScriptName Script
{
  eventIn SFWhateverType WhateverName1
  eventOut SFWhateverType WhateverName2
  field SFWhateverType WhateverName3

  # JavaScript begins here

  url "javascript:

    function WhateverFunctionName (Param1, Param2)
    {
      // Function definition
    }

  "

  # JavaScript ends here
}

# ...

# Usually at the end of the file
ROUTE WhateverObjectName1.WhateverFieldName1 TO WhateverObjectName2.WhateverFieldName2

A Script node can have however many eventIns, eventOuts, and fields. eventIn is used to ROUTE some outside node into the script, where the necessary logic is handled; eventOut is used to ROUTE some value set within the script to some outside node, usually to trigger an action; field is the local variables in the Script node. For a list of data types and detail information, see the Official VRML Specs Website.

Each eventIn should have a corresponding function with the same name as the eventIn field. The first parameter of the function is the value ROUTEd in to the eventIn. The second parameter (optional) is the currentTime time stamp when the event is ROUTEd in. To trigger a function in the script, ROUTE some node (e.g. a TimeSensor) outside the script to an eventIn corresponding to the function (same name as the function) in the script.

Once an eventOut is given a value (usually from within a function), the eventOut automatically ROUTEs out from the Script node to whatever they are ROUTEd to. To trigger an outside action from within the script, set the value of an eventOut, and ROUTE that eventOut to some node (e.g. a PositionInterpolator, a TimeSensor) outside the script.

ROUTEing scripts are usually placed at the end of the file.


Hints:

  • Putting the functions and the ROUTEing codes in a logical order helps in the debugging process, especially when the actions involve a long process that goes back and forth between the Script node and the outside (like the elevator code).
  • Use VRML style commenting (# single-line) anywhere in the file except in the inlined url JavaScript section - use JavaScript style commenting (// single-line, /* */ multi-line).
  • If there are hand-written scripts, use a VRML text editor to find syntax or symmantic errors before running the wrl file in a browser. There aren't many VRML editors, but a good one to use is VrmlPad. It's a shareware and is not too useful when need to save large files (the shared version only allows 64K max), but it's very handy in finding syntax or symmantic errors. VrmlPad's status bar shows the type of present errors in the lower right corner in highlighted background colors; double-click on the highlighted error type, and it will take you to the next line with the chosen error, which will be dot-underlined in color. There is also a "Next Error" button on the toolbar, the icon is a hammer with a curved arrow.

Optimization

The difference between a very nicely and smoothly rendered architectural scene and a real-time 3D model is that the former allows for rendering ahead of the time, and the latter requires rendering on the fly. Because of this, in order to reach the maximum navigation speed in the architectural model, some details need to be sacrificed; this includes the smoothness of surfaces, details in objects, resolution of textures, etc. The VRML language itself already has some features to enable fast real-time rendering such as the lack of shadows so that no shadows will need to be calculated for rendering; this is also part of the reason that VRML does not support all of the effects from 3ds Max, and the non-supported features are not exported to VRML files when using the 3ds Max exporter.

Our main approach was to reduce the polygon count, to shrink texture file size, to reuse textures, and some other more minor methods.


Recreating meshes as primitives when possible

VRML defines meshes by listing the coordinates for each vertex, which can be in terms of thousands when the mesh is even a bit complicated. On the other hand, it defines primitives by a built-in node type like Box and defines its few fields. According to the 3ds Max User Reference, spheres, cylinders, and cones also export as primitives. There might be others.

Thus, creating primitives instead of meshes can reduce file size. A primitive can be converted to a mesh at two mouse-clicks, but converting backwards is not as easy. We remade some cylinders and boxes that were originally meshes as primitives so that the exported file is much smaller. Making identical objects as "instances" of these new primitives will reduce file size even more. See the instances section.


(Re)Making identical objects as instances

This reduces file size by telling 3ds Max to automatically use DEFs/USEs keywords for geometry's -FACES and other nodes.

The exporter uses DEF for the first appearance of the object (the master) to assign it a name, then uses the USE keyword for all subsequent appearances of the object to reference to the master and to use its properties.

This saves the code to redefine the same shape every time and shrinks down the code to only 1 line.


Reducing polygon count in 3ds Max

3 Max modifiers to help reduce polygons and vertices:

  • MultiRes
  • Optimize
  • Vertex Weld

These can be found in the Modify Panel > Modifier dropdown list

MultiRes is the most extensively used method in the Calit2 virtual building. It allows directly typing in the desired percentage of vertex count, then automatically generates the image according to the set percentage. It is officially better than the Optimize modifier, as stated in the 3ds Max 9 User Reference from the Help menu.

Optimize sometimes can have an effect when MultiRes does not. However, most of the time, MultiRes reduces more polygons and gives better images that aren't distorted.

Vertex Weld combines nearby vertices according to the user-defined distance between vertices so that the mesh is clean. This works even when the Merge Vertex option in MultiRes modifier does not have an effect.

In this model, MultiRes usually reduces quite a large amount of polygons (reduction ranges from around 10% to 80% of the original), but sometimes we use MultiRes in combination with Vertex Weld. The Optimize modifier is seldom used in this model.


Shrinking texture map image file sizes

Texture map files occupy memory space and render time. We reduced a large amount of texture files from 512 * 512 to 256 * 256, which is four times smaller in terms of area. This reduced the size of the maps directory by half (from about 120 MB to about 57 MB), the texture memory, and thus sped up loading and rendering time.

A tip from VRMLworlds.com is to make map resolutions powers of 2, e.g. 512*512, 256*256, etc. "Doing this makes the textures look better in the vrml world, and also helps the scene render a little faster or use less video memory."


We mostly used TIF or PNG formats because of their preservation of image quality. PNG does have the advantage over TIF to preserve full image quality at a smaller file size, but TIF is more commonly used for professional and archival purposes. Most VRML articles recommend JPEG, GIF, and PNG formats because VRML worlds are commonly used for web applications and prefers a smaller downloading time. We use the TIF format instead because the virtual building is not meant for the web, and we have enough memory to render large texture maps to achieve an effect as realistic as possible. With JPG's compression, parts of the realistic feel will be lost.


Reusing textures

We need to manually edit the exported VRML file to use DEFs/USEs keyword for ImageTexture nodes so that texture memory can be conserved.

3ds Max exporter does not do this for us; instead, it uses a url field for all ImageTexture nodes, which results in a reload of a fresh copy of the texture file every time it is used. So if a texture file is being used 100 times in the model, the Max-exported VRML code will freshly reload that file everytime it is used, instead of just loading it once and using the copy in memory. This results in 100 times more memory use than necessary.

To edit the code, use any text editor with multiline replace function. We used NoteTab.

#old syntax example for all original Max-exported ImageTexture nodes
texture ImageTexture {
  url "SomeMapsDirectory/SomePic.tif"
}
#new memory-efficient syntax for ImageTexture node of the 1st appearance of the texture file 
texture DEF SomePicName ImageTexture {
  url "SomeMapsDirectory/SomePic.tif"
)

#new memory-efficient syntax for ImageTexture node of the 2nd-and-on appearances of the texture file 
texture USE SomePicName

The DEF keyword gives the first appearance of the file a name; and then the USE keyword in later appearances of the map file references that name so that the texture map does not have to be reloaded into memory again.

Misc. Debugging Ideas and Tricky Surprises

When testing the model, one important thing to keep in mind is that while navigating in a VRML world, the viewer can only be in one place at a time, meaning that the user can be immune to some effects that are obviously not reasonable to the developer. This is even more true for this virtual building since it is mostly used for demos. Because of this, we can ignore some specific details that have to be taken care of in real-life. An example is, when an elevator cab is in the process of travelling, say from the 6th floor to the 3rd, if the user presses a call button from the 4th floor, then the animation will start over from the 6th floor to the 4th, jumping from whereever the cab was in its travel process. When testing from far away with all the walls turned off so that the entire set of elevators from the 1st to the 6th floor can be seen, this effect is obviously incorrect. However, during a normal demo, the user will not be able to access more than 1 floor at a time, and they will not be seeing the interior of the elevator without walls, so it is unlikely that they will notice this effect. This saves some time for coding to ignore the call button event when the elevator is moving, especially when the cab movement process is the most complicated and involves most of the logic back and forth in the script.

Like anything else, the 3ds Max VRML exporter is not always perfect; it sometimes generates unwanted results that needs to be manually taken care of. Some instances of this are listed in the following sections.


Automatically Generated INTERPs and TIMERs

Symptom: In the Terminal running OpenCOVER, the line showing the polygon and vertex count keeps flying up the screen, and the two numbers of counts keeps increasing.

If there are grouped objects in a scene, after exporting the scene, open the VRML file and search for "INTERP" or "-TIMER". It is very likely that a ...-TIMER object has been automatically generated below the group name DEFinition, and its characteristic is that its definition is single-lined, its loop is TRUE, and its CycleInterval is the 3ds Max animation track bar time divided by 30 fps (if using the default track bar, 0-100 frames, then the CycleInterval will be 3.333). Along with the timer, sometimes a corresponding INTERP is generated and is ROUTEd by the timer. These timers and interpolations are the culprit of continuously generated polygons during run-time in OpenCOVER. The solution is to simply comment out the timer's definition and the corresponding ROUTEing lines; there are usually 3 in a set. If it seems that the interpolation is not routed to by anything else, it might be harmless to delete the entire definition, since it is often many lines long; but we have not test this thoroughly as to guarentee it.

On the other hand, if there are mesh animations in the scene, then these INTERPs and -TIMERs are necessary for the animation; leave them as they are in the file. Mesh animations are animations that involve sub-object level changes such as vertex or polygon generations. Simple translations, rotations, and scaling do not fall into this category; these usually do not need the automatic generated INTERPs mentioned above, which can be commented out in the usual case.


No Reusage of texture maps

Symptom: At OpenCOVER loading time, texture loading is very long, and when loading finally finishes, the Texture size printed on Terminal is no where near the maps directory size on disk.

3ds-Max-exported VRMl code tells the browser to freshly load the texture map every time it is used instead of reusing a previously loaded identical file.

To fix this, see "Optimization" > "Reusing textures" section above.


Light Direction / Leak

Unlike real-life lights, VRML lights do not light up themselves but light up other objects. Therefore the light source itself will not appear to be lit; the effect can only be seen from object being lit around the light source. Because of this, a problem in our virtual building is that when the sun is in the east, the western sky appears lit because the lighting direction is from the east and therefore towards the west, and the eastern sky appears dark. If we attempt to solve this by placing another light source in the west to light up the eastern sky, then the buildings would have both east and west sides lit, which is still not reasonable since the sunlight cannot be coming from both east and west. A VRML directional light is supposed to only shine on the objects in the same group as the light, so we tried grouping a directional light in separate groups from the other objects, but the directional light still shines on every object regardless of the hierarchy. We haven't found a real way to fix this. However, a practical solution is to look at the model from a direction that shows only the building, or shows half of the sky, etc., that will hide the incorrectly lit sky effect. One important thing to keep in mind is that while navigating in a VRML world, the viewer can only be in one place at a time, and it is less likely that the viewer would go outside the globe. Even if he/she does, the current buttons to control the sunlight will be far from reach, so most likely, it will not as noticeable to the viewer as it is to the model builder.

Because there are no real shadows calculated in VRML, an indoor light does not only light up the room, but "leaks" through all walls, ceilings, and floors since VRML ignores these planes that are supposed to block the light from entering other rooms. We had the problem of a light source placed on the 5th floor, and the light effect is seen on the 1st floor ground, which is lit. The supposed way to fix this is to change the radius field of the lighting node, but it seems that the radius field has no noticeable effect in OpenCOVER (we tried radius 5 and 500, but they turned out to be the same). So we used the attenuation field to dim the lights quicker using a value larger than 1 for the first value so that the leak does not reach too far. See the "Light Attenuation" section below for more detail.


Light Attenuation

Symptom: 3ds Max exporter simply does not export the correct attenuation.

A third-party exporter called Mark's shows a comparison of the 3ds Max exported attenuation effect with the supposed effect.

Unfortunately, the said exporter seems to only support up to Max version 4. Thus, to solve this problem, we can manually play with the attenuation field of the light node by trial-and-error. The attenuation field is a three-value vector, and in OpenCOVER, it seems that using any positive number for the second or the third value would just result in no lighting at all. For the first value, the larger the number is, the stronger the attenuation, and thus the dimmer the light. We have not experiment with negative numbers in these fields.

Attenuation field does not exist for directional light; it exists for both point light and spotlight.

Future Work

Elevators

Implement functions to simulate the building's:

  • Arrow light lighting up when cab arrives at user's floor
  • Sound effect when cab arrives at user's floor
  • Sound effect recorded from building's elevator (current ones are taken from another model; they aren't fully tested yet)


Realistic Environment

  • Stylized people walking along defined paths in the building
  • Realistic sensor information obtained from building's temperature, CO2, humidity, etc. sensors


....more to come

More Images

Exterior1 medium.jpg

The Calit2 building viewed in wireframe mode.


Exterior1 wire medium.jpg

The Calit2 Building shown with photo-realistic textures.


Interior1 medium.jpg

A view of the interior lobby of Calit2.


....more to come


Links and References

VRML97 (2.0) Specifications

VRML Specs main page (links to VRML 1.0 specs and zip files)


Lighthouse 3D Tutorials: TimeSensor Specs

Lighthouse 3D Tutorials: VRML Lighting Nodes

Mark Callow's VRML97-X3D 3ds max Export Plug-in

VRMLworlds: Exporting VRML from 3ds Max


Download VrmlPad 2.0 (shareware) from SoftEmpire

Download NoteTab Light 5.7 (shareware) from SoftSea