Drone Technology

Drone-Technology-02Drones—also called unmanned aerial vehicles (UAVs) or unmanned aerial systems (UAS)—are most simply described as flying devices that do not carry a human pilot. They can be remotely piloted or they can pilot themselves based on pre-programmed instructions. They can be equipped with GPS, on board computers, hardware, electronics, sensors, stabilizers, auto-pilots, servo controllers, and any other equipment the user desires to install. Drones can resemble fixed-wing airplanes but more commonly take the form of quad-copters, that is, rotor-wing aircraft that can take off and land vertically. Most people know that drones can be equipped with infra-red cameras (still and video), license-plate readers, “ladar” (laser radar that generate three-dimensional images and can be seen through trees and foliage), thermal-imaging devices, or even sensors that gather data about weather, temperature, radiation or other environmental conditions. All of this can be used to generate images, recordings or data that design professionals eventually will want to use in their business.

Drones could be a valuable tool in construction, widening the spectrum of what’s possible in architecture, according to architect Ammar Mirjan.

“We can fly [drones] through and around existing objects, which a person couldn’t do or a crane couldn’t do,” explains Mirjan. They can be programmed to weave simple tensile structures in the air, for example.

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How are aerial mapping drones helping architects?

Architects are exploring the many benefits of mapping drones for improving and expanding their businesses. Here are just a few examples:

The most popular application for small drones is aerial photography and video capture to track and share “before and after” progress over time.

Ability to securely collaborate on specific areas of interest with your team, contractors, and customers.

Tell the story of your project.  Show current and potential customers before and after fly-throughs of your job site so they can experience and appreciate the scale and impact of your work.

3-D point clouds with centimeter grade accuracy on progress, so you can get the precision updates you need to keep project approvals on time, without physically traveling to the site.

Get context for your project, plan your architecture with a full view of the surrounding area.

See 3D volumetrics so you know what you’re building on and can track progress.

Uses for Drones

  • Project documentation
  • Presentation + marketing
  • Architectural cinematography
  • Site analysis
  • Topographic mapping
  • Construction observation
  • Educational tool
  • Lead generation (working with Realtors)


According to an interview in Dezeen.com with Mark Dytham, architect and co-founder of Tokyo-based Klein Dytham Architecture, “Drones will transform the way buildings are designed, the way they look and the way they are used.

One way in which drones are proving to be a useful tool in architecture is through surveying. Due to their small size and relative ease of maneuverability, drones make an easy task of accessing difficult to reach places.

According to ArchDaily.com, “While using satellite imagery for site planning is common among architects, these visuals are often available in low resolution and produce less accurate data. Data collected by drones can completely eliminate the need for hiring land surveyors for creating topographic surveys. Instead, architects can use this information to build accurate 3D models of the terrain and site and import them directly into drafting and modeling software like Rhino.” In the past, architects would have relied on planes, helicopters, or satellite imaging for aerial footage.

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The 7 Dimensions of Building Information Modeling

It has increasingly become crystal clear that BIM represents the opening of the architectural design community and construction industry to interoperability. There is no doubt that it’s a long and tedious way to being fully developed, however, important steps have been made during the last decades and the future of construction looks brighter day by day.

What is BIM?

Building Information Modeling (BIM) is the process of creating information models containing both graphical and non-graphical information in a Common Data Environment (CDE) (a shared repository for digital project information). The information that is created becomes ever more detailed as a project progresses with the complete dataset then handed to a client at completion to use in the building’s In Use phase and potentially on into a decommissioning phase.

When we talk about BIM maturity we are essentially talking about the supply chain’s ability to exchange information digitally. The maturity levels from Level 0, through Levels 1, 2, 3 and beyond are often visualized via the maturity ‘wedge’ diagram conceived by Mark Bew and Mervyn Richards. Our article on BIM Levels Explained is a good place to start if you’re looking for more information.

BIM dimensions are different to BIM maturity levels. They refer to the particular way in which particular kinds of data are linked to an information model. By adding additional dimensions of data you can start to get a fuller understanding of your construction project – how it will be delivered, what it will cost and how it should be maintained etc. These dimensions – 4D, 5D and 6D BIM – can all feasibly (but not necessarily) occur within a BIM Level 2 workflow.

In this blog post we explore what it means to add different dimensions of information to a BIM process and explore what this looks like in practice and what benefits might be expected.


3D (The Shared Information Model)

3D BIM is perhaps the BIM we are most familiar with – the process of creating graphical and non-graphical information and sharing this information in a Common Data Environment (CDE).

As the project lifecycle progresses this information becomes ever more rich in detail until the point at which the project data is handed over to a client at completion.
4D (Construction sequencing)

4D BIM adds an extra dimension of information to a project information model in the form of scheduling data. This data is added to components which will build in detail as the project progresses. This information can be used to obtain accurate programme information and visualisations showing how your project will develop sequentially.

Time-related information for a particular element might include information on lead time, how long it takes to install/construct, the time needed to become operational/harden/cure, the sequence in which components should be installed, and dependencies on other areas of the project.

With time information federated in the shared information model planners should be able to develop an accurate project programme. With the data linked to the graphical representation of components/systems it becomes easy to understand and query project information and it is also possible to show how construction will develop, sequentially, over time showing how a structure will visually appear at each stage.

Working in this way is enormously helpful when it comes to planning work to ensure it is safely, logically and efficiently sequenced. Being able to prototype how assets come together before ground is broken on site allows for feedback at an early stage and avoids wasteful and costly on-site design co-ordination and rework. Showing how projects will be constructed visually is also handy when engaging with stakeholders, giving everyone a clear visual understanding of planned works and what the finished construction will look like with no surprises.

Adding sequencing information can be extremely useful, not just in the design phase, but earlier too, allowing for the feasibility of schemes to be assessed from the off. At tender stage this kind of information can allow initial concepts to be explored and communicated to inspire confidence in the team’s ability to meet the brief.

It’s important to note that working with 4D information doesn’t negate the need for planners who remain an integral part of the project team. Rather than creating programs as proposals develop, as is the case in traditional workflows, in a digital workflow planners can now influence and shape proposals from a much earlier stage in a project. Indeed, by being closer to the wider project team and providing feedback earlier in the process, there is the potential for planners to add significantly more value to a construction project.

3D-Guggenheim-Model5D (Cost)

Drawing on the components of the information model being able to extract accurate cost information is what’s at the heart of 5D BIM.

Considerations might include capital costs (the costs of purchasing and installing a component), its associated running costs and the cost of renewal/replacement down the line. These calculations can be made on the basis of the data and associated information linked to particular components within the graphical model. This information allows cost managers to easily extrapolate the quantities of a given component on a project, applying rates to those quantities, thereby reaching an overall cost for the development.

The benefits of a costing approach linked to a model include the ability to easily see costs in 3D form, get notifications when changes are made, and the automatic counting of components/systems attached to a project. However, it’s not just cost managers who stand to benefit from considering cost as part of your BIM process. Assuming the presence of 4D program data and a clear understanding of the value of a contract, you can easily track predicted and actual spend over the course of a project. This allows for regular cost reporting and budgeting to ensure efficiencies are realized and the project itself stays within budget tolerances.

The accuracy of any cost calculations is, of course, reliant on the data produced by multiple teams and shared within the Common Data Environment. If that information is inaccurate, so too will be any calculations that rely upon it. In this respect using BIM to consider cost is no different to more traditional ways of working. It is for this reason that quantity surveyors and estimators still have an important role to play, not only in checking the accuracy of information but also in helping to interpret and fill information ‘gaps’. Many elements of a project will still be modelled in 2D or not at all. There’s also likely to be differences between models in how things are classified and the cost manager will need to clarify and understand the commonality between what at first feel like disparate things.

An information model is likely to contain three types of quantity. Quantities based on actual model components (with visible details) which you can explore through the model are the most obvious. Quantities may also be derived from model components (such as moldings around windows) that aren’t always visible. The third kind of quantity is non-modeled quantities (these include temporary works, construction joints etc.). Unless the construction phase is modeled then the design model will show, graphically, design quantities but not the construction quantities. A cost manager is likely to be skilled in picking up the quantities that aren’t solely based on model components.

One of the advantages of extrapolating cost from the information model is the fact that the data can be queried at any time during a project and the information that feeds cost reports is regularly updated. This ‘living’ cost plan helps teams design to budget and because cost managers are engaged from the start of a project this allows for faster, more accurate reporting of costs at the early stages of a project. Compare this to a traditional approach where a cost manager’s report may be updated a few times during the early stages of a project with completed designs only fully costed at the end of the project team’s design process.

The cost manager may have to get used to working earlier and more iteratively than in a traditional process but has just as important a role to play in overall project delivery.

3d-perspective-section-cardigan-street6D BIM (Project Lifecycle Information; Sustainability)

The construction industry has traditionally been focussed on the upfront capital costs of construction. Shifting this focus to better understand the whole-life cost of assets, where most money is proportionately spent, should make for better decisions upfront in terms of both cost and sustainability. This is where 6D BIM comes in.

Sometimes referred to as integrated BIM or iBIM, 6D BIM involves the inclusion of information to support facilities management and operation to drive better business outcomes. This data might include information on the manufacturer of a component, its installation date, required maintenance and details of how the item should be configured and operated for optimal performance, energy performance, along with lifespan and decommissioning data.

Adding this kind of detail to your information model allows decisions to be made during the design process – a boiler with a lifespan of 5 years could be substituted with one expected to last 10, for example, if it makes economic or operational sense to do so. In effect, designers can explore a whole range of permutations across the lifecycle of a built assets and quickly get an understanding of impacts including costs. However, it is at handover, that this kind of information really adds value as it is passed on to the end-user.

A model offers an easily-accessible and understood way of extrapolating information. Details that would have been hidden in paper files are now easily interrogated graphically. Where this approach really comes into its own is in allowing facilities managers to pre-plan maintenance activities potentially years in advance and develop spending profiles over the lifetime of a built asset, working out when repairs become uneconomical or existing systems inefficient. This planned and pro-active approach offers significant benefits over a more reactive one – not least in terms of costs.

Ideally the information model should continue to develop during the In Use phase with updates on repairs and replacements added in. Better yet, a myriad of operational data and diagnostics can also be fed in to inform decision making still further.

3D-Sydney-Opera-House7D (Operations and Facilities Management)

Studies indicate that over 90% of total building lifecycle costs are related to facility maintenance and operations. Real estate and facility managers are increasingly showing interest in using BIM in facility management.

Some of the highlights of effectiveness of utilizing BIM 7D include:

  • Preventative Maintenance Scheduling: BIM can be used to plan and track maintenance activities proactively and appropriately by using the information about the building structure and equipment used in the facility. This type of preventative maintenance activities will help improve building performance, reduce corrective maintenance and emergency maintenance repairs and increase productivity of maintenance staff.
  • Sustainability Analysis: BIM integrated with other analysis & evaluation tools are used to track building performance data, which can be compared with specified sustainable standards to identify the flaws in the building systems. Facility’s sustainability program can be improved to better match the sustainability goals.
  • Asset Management: Assets of a building consist of the physical building, its systems, equipment and surrounding environment. Asset management is essential in short-term and long-term planning for proper upkeep of building assets. The bi-directional Building Information Modeling (BIM) integration into asset management software can help in better visualization of assets and aid in the maintenance and operation of a facility.
  • Space Utilization Management: Facility professionals and department liaisons can utilize BIM to effectively manage, track and distribute appropriate spaces and related resources within a facility. BIM space management application turns out to be beneficial in planning renovation projects and future needs, allocating space for proper usage of each corner of the building and tracking the impact of proposed changes.
  • Disaster & Emergency Planning: BIM can provide critical building information to improve the efficiency of disaster response plans and minimize any risk. BIM can be integrated with building automation system (BAS) to display where the emergency is located within a building, to find possible routes to the affected area and to locate other dangerous areas within the building during such emergencies.

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We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

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