Jaysuman Pusppanathan

Embedded system based optical tomography: the concentration profile

Purpose – The purpose of this paper is to view the flow concentration of the flowing material in a pipeline conveyor.Design/methodology/approach – Optical tomography provides a method to view the cross sectional image of flowing materials in a pipeline conveyor. Important flow information such as flow concentration profile, flow velocity and mass flow rate can be obtained without the need to invade the process vessel. The utilization of powerful computer together with expensive data acquisition system (DAQ) as the processing device in optical tomography systems has always been a norm. However, the advancements in silicon fabrication technology nowadays allow the fabrication of powerful digital signal processors (DSP) at reasonable cost. This allows the technology to be applied in optical tomography system to reduce or even eliminate the need of personal computer and the DAQ. The DSP system was customized to control the data acquisition of 16 × 16 optical sensors (arranged in orthogonal projection) and 23 ...

Desktop tomography system using planar ECT device

Miniaturized planar electrical capacitance tomography (ECT) device is fabricated using microfabrication method to accommodate eight planar electrodes to carry out electrical capacitance measurement using tomography technique. Fluids within the detection chamber are detected by the difference of the permittivity parameters. Stagnant and hydrodynamic multiphase samples such as liquidgas and liquid-liquid are tested. The eight-electrode planar array is fabricated on the copper plated printed circuit board (PCB) and the chamber is fabricated using polymer poly (dimethyl-siloxane) (PDMS). The images of the multiphase sample are reconstructing using Linear Back Projection algorithm (LBP). Computer interface software is developed to display the images of the fluid online. Experimental results show that the reconstructed images closely resemble with the composition of the multiphase sample within the detection chamber.

Initial Study On The Implementation Of Reflection Method In Ultrasonic Tomography

Matlamat utama projek ini adalah untuk mereka bentuk suatu sistem pengimbas ultrasonik dengan menggunakan kaedah pantulan yang dijana dan diterima oleh alatan ultrasonik yang lazim digunakan di dalam bidang perubatan. Disebabkan oleh kos yang tinggi dan konfigurasi yang rumit bagi sesetengah alat-alat perubatan yang berjenama seperti Philips dan Brauns, sistem pengimbas ultrasonik yang direkabentuk dalam projek ini adalah berhasrat untuk mengurangkan kos dan juga memudahkan konfigurasi. Pada asasnya, sistem pengimbas ultrasonik terdiri daripada dua bahagian; pemancar dan penerima. Dalam projek ini, satu mikropengawal pengimbas ultrasonik perubatan yang telah dipilih. Isyarat pantulan yang dikesan penerima pengimbas ultrasonik perubatan diperhatikan dengan menggunakan osiloskop digital. Sistem pengimbas yang direka kemudian diuji dengan mengimbas sebuah betik. Kata kunci: Tomography ultrasonik; pantulan; gambaran perubatan; pengimbas ultrasonik; pendekatan secara eksperimen The main purpose of this project is to design an ultrasonic scanner system which implements the reflection method through a medical ultrasound probe. Due to the high–cost and complex configuration of some of the well–known names in medical devices; such as Philips, and Brauns, the ultrasonic scanner system in this project is aimed to be cost effective and simple. Basically, the ultrasonic scanner system consists of two parts; the transmitter and the receiver. In this project, a PIC microcontroller was used in the transmitter circuit in order to produce a 2 MHz signal to excite the 2.25 MHz ultrasonic transmitter that exists in the medical ultrasound probe that had been selected, whereas the output or the reflected signal was obtain by tapping at the receiver of the medical ultrasound probe and was observed by using a digital oscilloscope. The ultrasonic scanner system was later tested by scanning a papaya. This project was verified by obtaining the reflected signals that resulted from the papaya scanning tests. Key words: Ultrasonic tomography; reflective; medical imaging; ultrasound probe; experimental approach