Close Range 3D Scanning

Documentation of objects has always been the foundation of material culture research and conservation. Replacing and amending traditional methods, 3D documentation is increasingly being used as it more fully captures the original nature of the object. Although it is possible to simply draw objects in 3D by hand in the same way as we would make drawings on paper, automated scanning techniques offer much more accuracy and precision. There are many different techniques used for capturing 3D data.1 For capturing objects of cultural value, none-invasive techniques are preferred. Three techniques are commonly used in archaeology and related fields today:

Laser scanning

Laser scanners measure distance by measuring the time a laser beam takes to get back to the scanning device.1  In 1960s this technique was developed to measure the distance to the moon.2 Today, airborne laser scanners are used to measure the surface of the earth in detail, while land based laser scanners can be used to scan objects of a range of sizes.

The main advantage over structured light scanners is that laser scanners are much faster in capturing large areas or objects such as building exteriors or interiors. Structured light scanners however are able to acquire higher precision.

Structured light

Structured light scanners scan a surface by projecting a light pattern over an object. The pattern deforms on the surface of the object, which is registered by one or more cameras. Software is used to accurately calculate the 3D shape of an object based on these deformations.

Structured light scanners are able to reach great precision because they sample the same surface several times. A drawback is that fixed position structured light scanners are bound to the size of the projected pattern, making it impractical to scan large objects. More recent scanners allow more free movement and object size is less of a limitation. They also do not work well in strong exterior light conditions as the projected light might not contrast enough with the surroundings. Hence, structured light scanners are best suited to record small to mid-sized objects under controlled conditions inside.

Structure-from-motion

Image based modeling3 is the technique of generating 3D models from a set of 2D images. A photocamera is used to capture a multitude of images from an object, which are fed into software that uses advanced image analysis algorithms to reconstruct camera position and distance. The technique can be used in combination with any kind of camera, even smart phones are effectively  used today as 3D scanners. However, lense type, camera resolution and setup determine the quality of the final model.

As photocamera's are used as scanning device, the technique is very flexible and scalable. One popular application nowadays is capturing drone footage, allowing for fast scanning of large areas. This way we are able to document buildings, excavations, and landcapes.

Projects

3D Restoration of Ferdi's Hortisculptures

2023-2024

Using 3D scanning to digitally reconstruct and restore sculptures in the Bonnefanten museum collection.

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Ferdi
Video made of the 3D model with simulated light and surface properties

THE ALLARD PIERSON’S CENTURIPE PYXIS

2022

A high resolution photogrammetric documentation and RTI data captures of the Allard Pierson's "Centuripe pyxis".

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Digitizing Roman coins at the Allard Pierson Museum

2022-2023

Using RTI and photogrammetric high-resolution scans to document a collection of Roman coins.

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coins scan
3D model of the stern decoration.

THE STERN DECORATION OF THE ROYAL CHARLES, RIJKSMUSEUM

2019-2021

A photogrammetric high-resolution scan of the mirror decoration of the Royal Charles.

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DRESSES FROM THE 17TH C. PALMHOUT SHIPWRECK

2018-2021

A photogrammetric high-resolution scan of the kaftan from the unique textile finds that emerged from the Palmhout wreck near Texel.

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Reconstruction of the bodice.
Render of the 3D scan of the original bone fragments and 3D models of the facial reconstruction by Maja d’Hollosy.

DOCUMENTING THE FACIAL RECONSTRUCTION OF A RUSSIAN SOLDIER, 1799

2018-2020

Visualizing the process of reconstructing a human face from fragments of an excavated skull of a Russian soldier who died in the battle of Castricum in 1799.

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SCANNING THE JARDIN D'EMAIL

2018

The Jardin d’Email in the museum's sculpture garden as well as the plaster models in the depot have been scanned in 3D using hand and drone photogrammetry.

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Drone photogrammetry capture of the Jardin d'Email.
Restoration of the Bishop weeper in process

THE BISSHOP WEEPER FROM THE TOMB OF GUY OF AVESNES

2018-2020

Reconstruction of a sculpture found on the tomb of Guy of Avesnes, Bisshop of Utrecht, who died in 1317 AD.

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Video made of the 3D model with simulated light and surface properties

THE ALLARD PIERSON’S CENTURIPE PYXIS

2022

A high resolution photogrammetric documentation and RTI data captures of the Allard Pierson's "Centuripe pyxis".

Read More

Digitizing Roman coins at the Allard Pierson Museum

2022-2023

Using RTI and photogrammetric high-resolution scans to document a collection of Roman coins.

Read More

coins scan
3D model of the stern decoration.

THE STERN DECORATION OF THE ROYAL CHARLES, RIJKSMUSEUM

2019-2021

A photogrammetric high-resolution scan of the mirror decoration of the Royal Charles.

Read More

Reconstruction of the bodice.

DRESSES FROM THE 17TH C. PALMHOUT SHIPWRECK

2018-2021

A photogrammetric high-resolution scan of the kaftan from the unique textile finds that emerged from the Palmhout wreck near Texel.

Read More

Render of the 3D scan of the original bone fragments and 3D models of the facial reconstruction by Maja d’Hollosy.

DOCUMENTING THE FACIAL RECONSTRUCTION OF A RUSSIAN SOLDIER, 1799

2018-2020

Visualizing the process of reconstructing a human face from fragments of an excavated skull of a Russian soldier who died in the battle of Castricum in 1799.

Read More

Drone photogrammetry capture of the Jardin d'Email.

SCANNING THE JARDIN D'EMAIL

2018

The Jardin d’Email in the museum's sculpture garden as well as the plaster models in the depot have been scanned in 3D using hand and drone photogrammetry.

Read More

Restoration of the Bishop weeper in process

THE BISSHOP WEEPER FROM THE TOMB OF GUY OF AVESNES

2018-2020

Reconstruction of a sculpture found on the tomb of Guy of Avesnes, Bisshop of Utrecht, who died in 1317 AD.

Read More 

  1. Some laser scanners work however with triangulation, in which case it must be teamed up with a camera. Yet others work with measuring phase differences between the outgoing and incoming beam
  2. In the Lunar Laser Ranging experiment: Wikipedia
  3. Also referred to as the related concepts Structure from motion or photogrammetry