Developing an Automated Explosives Detection Prototype Based on the AS&E 101ZZ System

Arvanitis, Panagiotis Jason

07 October 1997

This thesis describes the development of a multi-sensor, multi-energy x-ray prototype for automated explosives detection. The system is based on the American Science and Engineering model 101ZZ x-ray system. The 101ZZ unit received was an early model and lacked documentation of the many specialized electronic components. X-ray image quality was poor. The system was significantly modified and almost all AS&E system electronics bypassed: the x-ray source controller and conveyor belt motor were made computer controllable; the x-ray detectors were re-positioned to provide forward scatter detection capabilities; new hardware was developed to interface to the AS&E pre-amplifier boards, to collect image data from all three x-ray detectors, and to transfer the data to a personal computer. This hardware, the Differential Pair Interface Board (DPIB), is based on a Field Programmable Gate Array (FPGA) and can be dynamically re-configured to serve as a general purpose data collection device in a variety of applications. Software was also developed for the prototype system. A Windows NT device driver was written for the DPIB and a custom bus master DMA collection device. These drivers are portable and can be used as a basis for the development of other Windows NT drivers. A graphical user interface (GUI) was also developed. The GUI automates the data collection tasks and controls all the prototype system components. It interfaces with the image processing software for explosives detection and displays the results. Suspicious areas are color coded and presented to the operator for further examination. / Master of Science

airport security

re-configurable computing

Field programmable gate arrays

device drivers

SRAM system design for memory based computing

Zia, Muneeb

03 April 2013

The objective of the research was to design and test an SRAM system which can meet the performance criteria for Memory Based Computing (MBC). This form of computing consists of a Look-Up Table (LUT) which is basically memory array mapped with a function; the computations thereafter consist of essentially read operations. An MBC framework requires very fast and low power read operations. Moreover, the cells need to be read stable as major part of the computation is done by reading the LUTs mapped in the SRAM array. Design and measurement of a prototype MBC test-chip with SRAM system optimized for read-heavy applications is presented in this thesis. For this purpose, a prototype MBC system was designed and taped out. Essential study of the write-ability of the core LUT is also presented. The core memory array for function table mapping was characterized for leakage, write-ability and power saving associated with pulsed read mode.

Look-up table

Asymmetric SRAM

Spatial computing

Temporal computing

Re-configurable computing

Memory based computing

Pulsed read operation

Memory management (Computer science)

Random access memory