Using Rectangle lights

The basic premise of this approach is that we place a V-Ray rectangle light over every opening that leads from an interior room to the outside environment. In the case of our project scene, this would mean giving coverage to the circular skylights, the doors and also the elongated windows we see in the two long gallery rooms.

Obviously, setting up all of the 12 required lights in the scene would take quite a while and result in a lot of unnecessary repetition in our text here. So, for the sake of speed I have prepared a scene that already has most of the work done. I have, however, left us with just one final light to add to the mix. This will give us an opportunity to take a look at how we both create and set up the options for the V-Ray Rectangle light type.

From your Exercise_Files folder, open up the Daylight_Interior_03.skp file.

A quick examination of the scene shows that we already have lights placed over the skylights, the doors, and in one of the long gallery windows (north facing). All that remains is to add one last rectangle light to the south-facing gallery window. To do just that, let's first of all perform the following steps:

Although this initial positioning should work just fine, the last thing we want from our V-Ray light objects would be to create any extra noise or render artifacts due to having them inter-penetrating the geometry in the scene. To make certain this does not happen in this instance, let's perform the following steps:

As our light object was created at exactly the same size as the window opening, we do have a little bit of scaling that we need to do in order to get proper illumination coverage for the interior. To scale our light up, we can perform the following steps:

Having run through its creation, we will obviously want to check that everything is working correctly on the light. So, let's switch over to the South Facing Gallery Interior view by clicking on the tab, which will of course put us on the inside of the room. (If from this vantage point it seems to you that a little more scaling on the light object wouldn't go amiss, now would be the time to make that correction.)

One problem that we currently have is that our window is completely covered by the light object, giving us no ability to see through to the outside environment. Indeed, if we were to take a render at this point, our window opening would simply show as solid white.

Fortunately, the V-Ray rectangle light has a very handy piece of functionality that can be enabled from inside the V-Ray light editor. So let's perform the following steps:

Another option that we may well want to tweak while we are in the Light Editor, one that can help us more closely emulate the look and feel of light coming from the sky, would be its color. As we are already working with the premise of our render taking place on a clear sunny day, we would perhaps expect the color contribution from the sky to be quite strong, having quite an obvious blue cast to it. To set this up, let's perform the following steps:

Testing our shot views

Having walked through the basic process of adding and configuring a V-Ray rectangle light in a scene, our next job is to enable them all and take some test renders from our interior POV shot cameras. To do this, we could go into the V-Ray light editor and place a check in the Enabled option for each of the lights, one at a time. Or, to speed things up a little, we could just load the Daylight_Interior_04.skp file from the Exercise_Files folder which has all of the lights already turned on.

To get a clear idea of what our V-Ray Rectangle lights are contributing to the scene (in terms of illumination), we ideally need to take a number of renders from our interior views. Initially, I think we can take them using only the direct light contribution from the rectangle lights, but then it may also be worth taking a couple with the global illumination systems enabled. This will give us an idea of just how much light energy these substitute skylights are going to bounce around the interior environment.

As a final test, perhaps we can then take a render that adds the key or sunlight into the mix as well, giving us an opportunity to evaluate the ratio of key to fill light in the scene. This will show us whether or not any final tweaks will be required.

In order to save our test renders for comparison, we could set things up so that the images are saved directly to the hard disk using controls found in the Output rollout of the options editor. However, we will take this opportunity to look at a very cool option that can be enabled on the V-Ray frame buffer window itself.

With the POV – Main Gallery Scene view selected, let's click on the render button on the V-Ray toolbar to render our direct light image. Once that is finished, we can go ahead and save it to the hard disk by using the render history feature of V-Ray Version 2.0. This is a very handy set of tools that lets us quickly save the image shown inside the V-Ray frame buffer window to the hard disk and then, at a later point in time, load it back into the frame buffer for comparison with a different render. To show how this works, perform the following steps:

Next, we need to turn on our GI systems. So, let's perform the following steps:

For the final test render, we need to enable our key light. We can do this by performing the following steps:

The evaluation time

With the renders completed and saved, one thing that we really should follow as a standard practice would be to always perform a comparative evaluation by examining and measuring what we are seeing in the images against the artistic definition that we created at the outset of our chapter. Ultimately, the questions we need to answer are: am I (or are we) heading in the right direction with the lighting by using this particular approach? Can it produce the end result that we are after?

To show how we can use the render history feature on the V-Ray frame buffer to make such an evaluation, let's perform the following steps:

Instantly, we get a split screen in the V-Ray frame buffer window with our newly selected A channel render showing up on the left while the currently rendered frame is shown on the right.

The divider line between the two in the frame buffer window gives us the ability to slide left and right over the two renders. This means that we can compare various elements of the two and decide whether or not the changes we have made have brought about an improvement in the newer render.

In this instance, clearly the final result with both GI and sunlight enabled looks far more natural than the original Rectangle light-only render. Obviously, we do need to keep in mind here that we are working with all of our quality settings as per V-Ray's default settings, and also that we haven't applied any actual surface properties to our materials as of yet.

Using the GI skylight

Our rectangle light setup is clearly capable of helping us add a daylight feel to our interior; one big drawback besides the required setup time would be the fact that there are quite obviously a lot of direct lights now required in the scene, all of which need to draw on processing power in order to create light and shadow effects. This, as you have probably already experienced, can slow down our renders by quite a significant amount.

These kinds of drawbacks have to be carefully weighed against the quality and flexibility (or indeed lack of such) that we get from the fill light solution when we use this particular approach. Such considerations become especially important given that, as we have already noted, this particular method for creating a skylight effect is not the only option available to us when using V-Ray.

Another approach would be to actually mix and match the use of specific V-Ray light objects such as our Sun spotlight with the default environment GI (skylight) that we used in the previous chapter. To test that out with this scene we will need to first of all disable the sunlight component of our Sun & Sky system.

To help us explore this approach, open up the Daylight_Interior_05.skp file from your Exercise_Files folder. This version of our interior scene takes us back to being in complete darkness once again, ready to build up a lighting solution using the GI (skylight).

One important difference between this and the rectangle light approach, one that we need to think carefully about, is the fact that the rectangle lights we were dealing with initially are recognized as direct light sources by V-Ray. This means we get light whether V-Rays GI systems are enabled or not. However, the GI (skylight) is an indirect light source, and as such, can give no light at all unless the GI systems are enabled.

Clearly, the first thing that we need to do in order to work with that option would be to turn the GI systems on. To do that, perform the following steps:

By default, the GI skylight (with the TexSky map applied) has a V-Ray Sun element already enabled, which, of course, we are not using in this instance. To disable that, we need to perform the following steps:

With those steps taken care of we are, believe it or not, ready to render with our GI (skylight) enabled.

As you can appreciate, this approach is far quicker and easier to set up than the V-Ray rectangle light solution, which is definitely a big plus. Let's click on the render button on the V-Ray toolbar then.

In a very short while, you will see another advantage of this particular skylight approach: it also renders far quicker than our array of V-Ray rectangle lights. This, of course, doesn't mean that there aren't drawbacks to this particular approach as well.

For one thing, our render shows that the occlusion or contact shadows in the scene are nowhere near as defined as they were with our V-Ray rectangle lights, and we also see a much stronger color cast in the environment that is not as simple to control as it was on the rectangle lights. There we had a simple color swatch, whereas here, because the V-Ray sky (or TexSky) map has been designed to be physically accurate with respect to both its light energy and the coloration it adds to an environment, the V-Ray sky map has no direct color control option as such.

As you can see, this option's physical accuracy can sometimes limit our ability to exercise artistic license in setting up a lighting solution. One quick and easy way to make a big change to the color coming from the sky map would be to change the algorithms being used to compute the sky model itself. To do this, we would need to perform the following steps:

If we click the render button on the toolbar now, we get (as you can see in the render) a much less saturated look from our skylight.

One potential drawback of using this option, however, is that because this color model has been designed to mimic an overcast sky, we do see a noticeable drop in the light energy levels that it outputs.

We could compensate for this drop by using the intensity multiplier value next to the map button. In all honesty though, if we want or need more control over the color quality of the skylight we are creating, we may decide that using the V-Ray Sky (TexSky) map is not really the best approach. Instead, we could decide to make use of a solid sky color, as we were in fact doing when using our rectangle light setup. To do this using the GI (skylight), let's follow the given steps:

If we were to take a render now, we would see that the level of color saturation added to the environment has been greatly reduced. Unfortunately, our level of illumination has also been greatly reduced, which is not really what we want. To counteract this, we can enter a value of 15 in the GI (skylight) multiplier field. This will take us back to roughly the same illumination level that we were getting from our V-Ray sky map.

At the end of this series of steps, we should end up with a render that looks like the following screenshot:

Again, with our Sun spotlight enabled, the GI (skylight) option would give us a very acceptable natural daylight simulation. One of the drawbacks of using just the GI (skylight) color swatch, however, (a drawback that also applied to our rectangle light setup) would be the fact that we are lacking any real variation from the skylights color contribution. When using the V-Ray sky map, we automatically get color shift and variation in the sky map as defined by the position of the V-Ray Sun in the sky. This is not so when using a flat color as we are here.

Another problem we see in this approach is the relative weakness of the occlusion or contact shadows in the scene. As this was one of the strengths of the rectangle light approach, this lack becomes very apparent here.

As with every aspect of rendering, the lighting choices available to us mean we are constantly trading the benefits of any particular approach with its drawbacks.

Trying out the Dome light

One skylight option available that would certainly improve the occlusion shadows in the scene would be the (new to V-Ray Version 2.0 for SketchUp), Dome light. This light takes its name from the fact that it provides us with a 180 degree, hemispherical dome of light that can give perfect skylight coverage to any scene. Now, of course, the GI (skylight) tool that we have just been working with does exactly the same thing. The big difference with the dome light, however, is that it doesn't need V-Ray's GI systems enabled in order to work given that it is, in fact, a direct light source. This, of course, is what gives it the ability to create much stronger occlusion shadows than its GI (skylight) counterpart.

To take a look at this powerful lighting tool, open up the Daylight_Interior_06.skp file from your Exercise_Files folder. This again resets the scene, bringing us back to complete darkness in our renders.

To create a Dome light in the scene, we need to perform the following steps:

Once created, you should have something that looks pretty close to the screenshot we have here:

To set up our dome light's color and intensity options so that they match up with those of our previous skylight attempts, let's follow the steps given here:

If we were to take a render at this point, I am pretty certain that you would feel a little disappointed with the final result, as the completely dark areas and the noise levels present in the image would present us with a very ugly-looking render. To improve things considerably, let's again add GI into the mix by performing the following steps:

If we now switch back to the POV – Main Gallery view and take a render, we can see that things are starting to look reasonably promising.

Of course, we still have a number of issues that would need to be dealt with here, not least of which is the high level of noise still present in the scene. At some point we are going to have to work with V-Ray's sampling controls to clean things up considerably here.

Adding a High Dynamic Range Image to the mix

We are also still lacking any color variation in our sky model due to the fact that we are once again only working with a solid color in the dome lights controls. There is, however, one more option available to us that can help add a little bit of color variation back into this shot, one that just happens to work exceptionally well with the dome light: the use of a High Dynamic Range Image (HDRI) in the dome lights texture map slot.

To demonstrate how this works, I am going to make use of the fantastic IBL spherical map resources that can be found at http://www.hdrlabs.com/sibl/archive.html. The specific archive or set of maps that I will be working with are entitled Etnies Skatepark, so if you want to follow along with me over the next steps, feel free to download and make use of this same free HDRI archive.

The specific map from the set that I will use here is one that has been especially prepared for use in lighting. It is a much smaller file (both in terms of resolution and disk space) that has had a blur operation applied to it so as to help prevent adding any unnecessary artifacts to the render.

To add the HDRI to our dome light, let's perform the following steps:

One major issue that would arise if we were to render the scene using our current setup would be the fact that the HDRI we are using was captured with the Sun high in the sky and in plain view. This means that we have inadvertently created a situation in which (with our V-Ray spotlight enabled) we will essentially have two Suns in the scene, both potentially casting conflicting shadows. (As our interior is not meant to be set in a galaxy far far away, this problem could seriously detract from the photographic quality of our final render.)

We can, however, create a little bit of a workaround by placing the Sun found in the HDRI at roughly the same location in world space as that occupied by our V-Ray spotlight. Now, while this is clearly not a perfect solution, it will hopefully cut out the chance of having two sets of shadows being cast in differing directions. To set this up, let's perform the following steps:

What we get now (as the render clearly shows) is an image that has a very natural looking range of colors, especially in the areas where the sunlight from the HDRI is coming through the skylights, adding slightly warmer tones to the floor. We may feel that the blue color cast we get from our sky is still a little strong, but before we go ahead and make a final evaluation of that, we need to turn our Sun spotlight back on. To do that, we need to perform the following steps:

As we can see, doing so evens out the color cast in the scene quite a bit. This means that we can probably leave any final analysis and possible alterations until we have gone ahead and added materials to the scene as these will make a difference to the way that color from our light sources behaves in the environment.

Bringing the sky back into the view

One thing you may have noticed with the dome light renders that we have been taking here is the fact that our sky color (as seen through the circular skylights in the ceiling) has remained pretty much white, which may or may not be acceptable depending on what we are wanting from the scene. For my part, even though we could technically take care of this issue during postproduction, I would prefer to have a little more control over the coloration of the sky in render as it were so as to introduce a little more blue into the environment. To do that, let's follow the given steps:

We can now go ahead and make use of V-Ray's Reflection/refraction (background) control to set up an image as the backdrop for our render. We can, of course, use any image we want here, but my personal preference would be to use either a non-blurred version of the same HDRI that is providing the skylight in the scene, or use a nice clean V-Ray sky map. To do the latter, we need to perform the following steps:

Our render shows that we now have some blue back in our sky that can easily be controlled and made lighter or darker whenever we wish.

Wrap up

Having run through a number of approaches then with regards to creating fill or skylight in the scene, I feel that this final combination of the V-Ray dome light and HDRI gives us the most versatile option to create the kind of lighting mood that we settled on in our artistic definition at the start of the chapter.

For this reason, I am going to save this file just where it is so that we can come back and use it when we get to the point of creating realistic materials for our scene geometry.