Light based techniques continue to gain momentum in different spheres of diagnostic and therapeutic applications as a result of their non-invasive, noncontact properties. One such technique is Optical Coherence tomography (OCT). Since it was first reported by Huang in 1991[1], OCT has made significant strides in different fields from dermatology and ophthalmology to polymer characterisation and bio-metrics[2-4]. In South Africa, the technique is still emerging although it is being used for eye examinations by ophthalmologists. The type of OCT system employed can be a simple, cost effective solution or a complex, highly specific and fast system depending on the application. As part of a larger project, the CSIR National Laser Centre has designed and built a high speed OCT system that can image a large surface area (25 by 25 mm) to a depth of 11 mm (sample dependant). Resultant 3-D images (512 x 512 x 2048 pixels) are acquired in less than 3 seconds. The performance of the system compares adequately with many commercially available systems which usually image smaller areas [5-6]. The heart of the system is a 200 kHz swept laser source and two axis galvonometer based scanner. Signal acquisition is made possible through a high speed analogue-to-digital converter capable of speeds greater than 1GS/s. This paper will give an overview of the system and elaborate on the design of the data acquisition system and the initial results that have been obtained.
Reference:
Sharma, A. 2016. A high speed OCT system developed at the CSIR National Laser Centre. 61st Annual Conference of the SA Institute of Physics, University of Cape Town
Sharma, A. (2016). A high speed OCT system developed at the CSIR National Laser Centre. South African Institute of Physics (SAIP). http://hdl.handle.net/10204/9122
Sharma, Ameeth. "A high speed OCT system developed at the CSIR National Laser Centre." (2016): http://hdl.handle.net/10204/9122
Sharma A, A high speed OCT system developed at the CSIR National Laser Centre; South African Institute of Physics (SAIP); 2016. http://hdl.handle.net/10204/9122 .