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3D Laser Scanning: The New Industry Standard

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When we first started laser scanning back in 2005, we replaced some of our total station surveying equipment with scanning technology. As much as anything, this was a great way for us to learn how to use the technology and understand its capabilities and limitations.

Early on, much of the work we did involved transportation projects and large complicated intersection surveys. There were many immediate benefits. For one, our surveyors were no longer put out into traffic and in harm’s way.

Another benefit was that we didn’t have to drive across town or across the state just to check on a few ambiguous points in a survey. Instead, we could just go back and look at the point cloud.

Today, in 2012, the entire world of architectural and engineering design and construction has changed. While before we had to convince clients of the benefits of using laser surveys, we now have a growing client base that simply will not consider starting a project without one.

In addition to providing accurate spatial information to civil engineers, plant designers, architects, contractors – and even insurance companies and crime scene investigators – laser scanning saves both time and money.

The truth is that in very complicated environments – like a mechanical heating and air conditioning plant room or a baggage room in an airport – the cost of scanning is nominal when compared to the total cost of the project.

Here are four primary reasons 3D laser surveys, or high-definition scanning, is quickly becoming the new industry standard when it comes to making precise measurements in complicated environments:

Reason #1: Scanner Speed

The speed of scanning has changed dramatically compared to what it was just seven years ago.

The first scanner we purchased (and still use today) took one hour for a 360-degree spherical orbit. Today, with our current scanners, it takes just six minutes.  This speed enables us to take many more scan set-ups than we used to take.

With our phase-based high speed scanner, we can now get 40 to 60 scans per day, which is very adequate to cover a large two-story mechanical room. To get the same amount of scans seven years ago would have taken a week.

In areas like these, it is the detail we look for, not the range. In extremely complicated areas, we make a set of scans on all sides. This data is invaluable to designers because it allows them to avoid interferences that often occur in these types of areas.

Reason #2: Software Improvements

Improved software programming has also contributed to the widespread acceptance of scanning technology.

I remember talking to clients back in 2005 and our message was something like this, “We will scan for you, then give you a 2D deliverable set of drawings that you can use to design your project.” When they would ask if they could use the point cloud in their design, our answer was always the same: “Yes, but you will have to buy $10,000 worth of software.”

As you can probably imagine, this was not an easy sell.

Fortunately, today Bentley, AutoCAD and Revit all have point cloud engines in them. The difference between an engine and a viewer is that we can now load a point cloud into an “engine” for a client and they can use the data in the design without having to purchase expensive “point cloud” software.

In fact, one of the takeaways from a scanning conference I recently attended was that all of the major software providers are moving to full 3D software design systems. They finally understand what we have known for years. Why would you survey in 3D, flatten the data to 2D, design in 2D then build in 3D? It just doesn’t make sense.

Reason #3: Clash Detection

This alone is worth the cost of a 3D laser survey.

Consider that if a project is modeled in the design phase, the completed final design – including the MEP systems, air handling systems, structural system and all of the architectural design – can be placed within the point cloud and clash detected. Anything that interferes with another system can be seen immediately and corrected before construction.

This is huge! What prudent engineer, designer or contractor would not want this advantage?  How important would this be to an owner?

Reason #4: TrueView or 360-Degree Spherical Photography

This technology has also improved quite a bit in the last seven years. When we first started scanning, we were fascinated with the fact that scanners could take photographs of the surrounding area, and then take that photographic data and overlay it with the scan data to make general measurements to the environment.

Unfortunately, back then the on-board camera was not as good as we had hoped and sometimes the pictures would come out octagonal and disjointed. As the process became more refined, we were able to mount a high resolution camera on the scanner and produce a crystal clear, color spherical photograph of the site.

This is a big step because it allows you to view a site from any scan set up. You can add text and information to the photographs and then e-mail a specific view to a client across the country or across the world. (In this case, some of our clients pay for our scanning fees with their savings in plane tickets!) This tool also enables clients to look out from the center of every scan and saves lots of time and discussion as to what is or is not located in the area of interest.

High definition scanning has quickly evolved from an emerging technology to an industry best practice when it comes to complicated projects. The construction process always includes many unknowns and the chance of design and construction errors is always high.

Why put yourself in the position of having to explain how a construction project was slowed down or over-budget because a laser scan was not the foundation of the project?

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Tate Jones has over 40 years of experience in land and aerial surveying and was one of the country’s earliest adopters of 3D laser scanning technology. A nationally recognized expert in the field of 3D data capture, he has worked with hundreds of clients in the engineering, architectural and construction industries. Contact him at tjones@lasurveying.com,  tjones@3DLaserSurveys.com or visit www.3DLaserSurveys.com.

Scan to BIM: The evolution of scanning technology

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The truth is, scanning is the only cost-effective way to collect the existing world.

You simply can’t go into a cathedral, petroleum refinery, or metropolitan multi-use entertainment facility and measure with rulers and expect to get the accuracy you need to confidently design renovations.

Laser scanning is the only way to do it.

Up until recently, BIM users would take a set of “asbuilt drawings” put them into a 3D modeling program and create a computer model to work from. Now, after several years of doing that, the harsh realization has surfaced that there are many discrepancies between the “record drawings” and the actual environment to be constructed.

If it’s sheet rock and wood, it can be adjusted to fit. But if it’s glass, steel, concrete or mechanical equipment, a seemingly small error can grow very costly as it is much harder to warp and bend. (Putting expensive new equipment into an area that is too small is a nightmare for the installer, designer, engineer and the insurance company.)

These new 3D laser scanning technologies have dramatically changed the surveying industry – and they have changed it fast. But to really understand the evolution, let’s take a step back….

2004: 360-Degree Scans
The first 360-degree scanners came onto the scene around 2004. Before that, if you wanted to scan something above your head, you had to tilt the scanner back and scan at a steep angle, as most only had a 120-degree scan ability on the vertical axis. Several companies came out with full straight scanners about this time that made it much easier.

2006: Time-of-Flight Scans
The next evolution was time-of flight scanners. In 2006, a time-of-flight scanner took about 45 minutes to one hour for a complete 360-degree scan. If you could do 8-10 scans a day, you were doing very well. Today, the same can be done in about 12-15 minutes, depending on the density you want a scan.

At our firm, our first scanning projects were roads. In a very complicated area, we would scan 1”X 1”. The time-of-fight scanners back then could collect 4,000 points per second. Now they can easily collect 50,000 points per second!

2008: Phased-Based Scans
Today’s phase-based scanners collect 2,000,000 points per second and can create a ¼-inch x ¼-inch pattern at a distance of about 100 feet. This is incredible and as fast and dense as the average user needs. The hardware will eventually get better, faster and cheaper, but phase-based scanning is effective, stable, and provides the ability to scan almost anything in a reasonable about of time.

Present: Scan to BIM
Today, the big research money is going towards Scan to BIM technology, which converts billions of points in the point cloud into useful data.

Several companies have begun addressing this including small independent companies like Pointools, which came up with a way for scanners to recognize flat surfaces. (As small as this may seem, it is a huge advancement.) The program will also recognize pipes and model them automatically about 50% of the time. (Another major advancement.)

Now many of the pipe programs are getting to the same place and advancing the ball. Currently, we are at what I call the “Model T Ford” in software programs, but every year the programs get better.

The next evolution
Having now scanned may very complex areas in industrial sites, we have had a chance to compare them to the asbuilt drawings. In the horizontal view, they are generally close geometrically to the actual. But in their vertical axis, the pipes and duct work in the asbuilt drawings are rarely correct.

There are many reasons for this, but most often it is because the process is so difficult that when an installer sees an easier path, he generally takes it.

“Record drawings,” or asbuilt surveys, are rarely done after the work is complete. Typically, the conversation goes something like this: “Here are the design drawings. Redline any changes that you made.”

There is not a lot of motivation to do a totally new survey. But if a design team takes these documents and models them into their computer programs, they are unknowingly creating multiple problems for the contractor on the new job.

We recently took a set of asbuilt documents for a complex project, modeled them and then compared them to the point cloud to do a clash detection to determine potential interferences. The outcome was eye opening.

Few of the pipes, ducts, waterlines or fire lines in the ceiling were in the place shown on the record drawings. If these documents had been used, the MEP contractors would have spent ten times our fee “field fitting” the new utilities inside the old.

With the utility and cost of laser scanning, it would be smart to use one on every renovation project. If for nothing else, insurance! Just one field fit can sometimes cost far more than the scan itself.

If you scan the environment and put the proposed design into the point cloud, you can tell in just a few minutes where the major interferences will be. We have found conflicts that would have taken upwards of $100,000 to fix if they had to be field-changed during construction. Some were fatal flaws in the required design clearance that could not have been achieved and a totally new design would have had to been submitted.

Scanning to BIM is a big and extremely important step in surveying. Right now, it is the design software that is trying to catch up with the scanning potential. Already this year, several new programs have come out that are much better at accepting point clouds and computer models, but they still have a long way to go.

Not having a design based on a laser scan of the actual environment is a risk that few designers should take. I know I wouldn’t want to tell an owner that there is a construction problem that could have been avoided with a relatively inexpensive laser scan.

Laser scanning has evolved from a “luxury” to a best practice and it’s not a step that any prudent designer should skip.

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Tate Jones has over 40 years of experience in land and aerial surveying and was one of the country’s earliest adopters of 3D laser scanning technology. A nationally recognized expert in the field of 3D data capture, he has worked with hundreds of clients in the engineering, architectural and construction industries. Contact him at tjones@3DLaserSurveys.com or visit www.3DLaserSurveys.com.

A 3D laser survey can save you thousands – just ask America’s busiest airport.

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When the time came to remove and renovate the existing underground baggage conveyor system in America’s busiest airport, the action never stopped.

The contractor hired for the renovation had a seemingly impossible task: build a new conveyor system while the old one was still in operation. No matter what, the luggage movers had to keep going.

Together, the contractor and a team of laser surveyors spent seven days scanning the site with high-speed scanners. They worked at night, when airport traffic was lightest, and when the final registered point cloud was compared to the proposed 3D model of the new conveyor system, critical clashes were detected.

By uncovering the interferences early, the contractor saved thousands in construction and re-manufacturing dollars.

Click here for the full case study.

High-definition scanning is changing the construction, architecture and engineering industries. The beauty of laser scanning is its ability to gather detailed data that the client doesn’t even know they need at the time, but will prove useful down the road.

In addition to being incredibly precise, scans can be used to produce point clouds, digital color photos, survey-quality files, computer models and videos from the scans of multiples views. You can insert animation or virtual buildings, roads and people to show proposed areas; or insert design drawings from BIM to check for clash or interference.

And once the site is scanned and processed, anyone – from analysts to engineers – can access it anytime. All you need to check and recheck engineering quality data is a desktop computer.

The cost savings of avoiding reconstruction and re-engineering far outweigh the cost of the scan itself. And, as with most things, isn’t it cheaper to get it right the first time?

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Tate Jones has over 40 years of experience in land and aerial surveying and was one of the country’s earliest adopters of 3D laser scanning technology. A nationally recognized expert in the field of 3D data capture, he has worked with hundreds of clients in the engineering, architectural and construction industries. Contact him at tjones@3DLaserSurveys.com or visit www.3DLaserSurveys.com.