Leyony Geomatics and Surveys Ltd

23/08/2019

Article
What Do BIM, GIS, IoT, BMS, Telemetry and CAD All Have in Common? - 22/08/2019
Ilka May, Mark Bew


Over the last three years, building information modelling (BIM) has undergone rapid development around the world. The value chain of design, construction and operation of built assets faces various challenges of change, some of which are of a technological nature. These include the transition from drawing in 2D to modelling in 3D with object reference and linked information. There is also an explosive increase in the volume of data on projects, including from new recording methods such as unmanned aerial vehicles (UAVs or ‘drones’), lasers, geo-radars, and the increased use of sensors and data transfer devices on the Internet of Things (IoT). As that data comes in so many shapes and sizes, there are continual efforts to enable interoperability. In connection with integration, we need to ask ourselves: what do BIM, GIS, IoT, BMS, telemetry and CAD all have in common?

Firstly, let us explore what exactly ‘interoperability’ means. The interoperable approach uses a fixed schema, which enables the theoretical bi-directional exchange of data between two compliant applications. However, the approach has proved unreliable at both data exchange and bi-directional support due to technical compliance by large software vendors and the complexity of setting up such tools.

Therefore, we should perhaps be more concerned with data integration which connects a superset schema to enable all data to be exchanged, whatever it may be. This is especially attractive in this area of engineering due to its complexity and the ever-expanding need to incorporate other contextual data to add operational and service value to asset information.

In connection with data integration, we need to ask ourselves what BIM, GIS, IoT, BMS, telemetry and CAD all have in common. The answer: they are no ordinary data; they all benefit from being geolocated in some way. Many professionals in the world of GIS have long understood the benefits of geolocation. In engineering, on the other hand, the approach to geolocation has often been from the microscopic perspective of the asset being built relative to itself, rather than relative to the wider world or city view.

This micro/macro perspective is interesting as it starts to provide context for the challenges of integrating geolocated information. At first glance, it looks easy. After all, there are only so many types of location methods. We can map from one to the other, so geolocation must surely provide the ultimate primary key to all data in the world, right? Well, maybe, but is this really true?

The issues of grids (including snakes), topology, moving grids and planets not being as round as we would like are all interesting, well-known and well-documented challenges in the GIS community. A less-discussed wider challenge is: even if we did geolocate all of the data types described above, what could we do with that information? And how does the state and fidelity of the data affect its ability to be used safely for which purposes? The figure shows a number of different data types and potential uses.

This illustrates how each part of the vast community involved in the built and natural environment has developed an ecosystem that is suited to its needs. Engineering and architecture are moving towards an integrated world of geometry and data, described by objects. The accuracy of the geometry can be to several decimal places; however, the typical tolerance of construction can be up to 50mm. As we move along the axis and reduce the fidelity of data, the use cases change: from service provision to planning and strategic purposes. Data also has a temporal component; it ages as the asset ages. Briefing data is very different from handover data, and sensor data provided by the emergent IoT world offers yet another dimension.

This leaves us with another fascinating question: which piece of data is correct, and how do I know I have that piece of data in front of me to solve my current problem? Data provenance and state are two concepts we have not heard about much to date. But get ready… you soon will.

A less-discussed wider challenge is: even if we did geolocate all of the data types described above, what could we do with that information? And how does the state and fidelity of the data affect its ability to be used safely for which purposes? The figure shows a number of different data types and potential uses.

Over the last three years, building information modelling (BIM) has undergone rapid development around the world. The value chain of design, construct...

18/04/2019

18/04/2019

18/04/2019

A major fire erupted at the Notre Dame Cathedral in Paris on Monday.
The cause of the blaze remains unclear, but officials do not suspect terrorism or arson.
About 50 people are involved with the investigation.
So far, about a billion dollars have been pledged to help restore the landmark.

Luckily the Geomaticians in Paris had done a Laser Scan of the Cathedral. The initiative and its contributions of Surveying to a redevelopment of the Cathedral cannot be over emphasized.
Below is an introduction into 3D Laser scanning. Excerpts from CadPlan UK.

3D Laser scanning is essentially the swift capture of three-dimensional information reflected from an object or surface to a light sensor.
It creates a 3D construct called a “point cloud” made from multiple scans that have been unified through a process of “registration”.

Once the point cloud data is processed, traditional deliverables; 2D plans, elevations, and sections can be readily extracted, or used for fly-throughs and contextual purposes.

3D modelling (BIM) is simplified using the point cloud data as the initial reference, the point cloud by itself can serve this purpose, saving many hours of digital model building.

Precise measurements can be taken between individual scan points, edges, and planes.
3D Laser Scanning reveals deformation from poor construction or the cumulative effects of time.
After the scans are registered, a three dimensional database is established that can be used throughout the building’s lifecycle, or to aid in reconstruction should damage occur in the future.

Additionally, remarkably sharp and descriptive photographic data is fused with the point cloud and can be easily viewed as dynamic panoramas. These images are dimensionable and can be annotated in most cases.

Similar to a camera, a laser scanner is a “line of sight” device: it sees what the viewer observes -it cannot see through objects. Dark, shiny surfaces do not scan as well as lighter, non-reflective materials.

In the reconstruction of the Cathedral, this video above will surely give am exact definition of the building as it were. All exact elevation points can be set out at exact heights..

Surveying still remains the bedrock of all meaningful developments. And that's what we do in Leyony Geomatics and Surveying Ltd..

21/03/2019

The bedrock of all meaningful developments... Surveying

https://surveyorsday.com/global-surveyors-day/20625125

05/03/2019

Be not exhausted...for ur wait will be flourished with abundance in this month.... Good morning

25/12/2018

Wishing you all a merry Christmas and a Prosperous New year in advance.

02/09/2018

Condominium Surveys PWC Lekki 2015 SpaceLab, LLC - Land Surveyors & Geo-Geeks Paul's land surveying and estate management ferm Adron Homes And Properties Ltd Property MAX Results LTD Lekki gardens estate

03/06/2018

Route Survey. A route survey supplies the data necessary to determine alignment, grading, and earthwork quantities for the design and construction of various engineering projects such as roads, railroads, pipelines, and utilities. When accuracy matters, your choice of land surveying companies matters.
At Leyony Geomatics and Surveys we have experienced professionals capable of handling such projects with state of art equipment. Our aim is always to deliver the best service through a Technologically assisted system, meeting clients and it's project requirement with best practices and guaranteeing satisfaction.
Distance is not a problem. This project below was done far away In Gombe state.
Reach us for your works.

24/05/2018

Topographic Survey

A Topographic Survey is a survey that gathers data about the elevation of points on a piece of land and presents them as contour lines on a plot. The purpose of a topographic survey is to collect survey data about the natural and man-made features of the land, as well as its elevations. Topographic maps are used to show elevations and grading features for architects, engineers, and building contractors....
This project was done in a remote village in Kogi state Nigeria. The objective of the project was to acquire topographic data to control run off water from the mountain tops from precipitations and underground water causing erosion in the village.
A Topographic map was created and all details were well represented especially the roads and drainage networks.